Plant adaptations to severely phosphorus-impoverished soils

•Mycorrhizas increase the volume of low-phosphorus soil that can be explored by roots.•Cluster roots release carboxylates, which mobilise sparingly available soil phosphorus.•Species with cluster roots are common on soils with a low phosphorus availability.•Phosphorus availability may be low because...

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Published in	Current opinion in plant biology Vol. 25; pp. 23 - 31
Main Authors	Lambers, Hans, Martinoia, Enrico, Renton, Michael
Format	Journal Article
Language	English
Published	England Elsevier Ltd 01.06.2015
Subjects	Adaptation, Physiological aluminum biomass Carboxylic Acids - metabolism crops hydroxides hyphae iron mycorrhizae Mycorrhizae - physiology oxides phosphorus Phosphorus - metabolism plant breeders Plant Physiological Phenomena Plant Roots - metabolism Plant Roots - microbiology Plants - metabolism Plants - microbiology roots soil Soil - chemistry soil solution
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Abstract	•Mycorrhizas increase the volume of low-phosphorus soil that can be explored by roots.•Cluster roots release carboxylates, which mobilise sparingly available soil phosphorus.•Species with cluster roots are common on soils with a low phosphorus availability.•Phosphorus availability may be low because total soil phosphorus concentrations are low.•Phosphorus availability may also be low because the soil phosphorus is sorbed onto soil particles. Mycorrhizas play a pivotal role in phosphorus (P) acquisition of plant roots, by enhancing the soil volume that can be explored. Non-mycorrhizal plant species typically occur either in relatively fertile soil or on soil with a very low P availability, where there is insufficient P in the soil solution for mycorrhizal hyphae to be effective. Soils with a very low P availability are either old and severely weathered or relatively young with high concentrations of oxides and hydroxides of aluminium and iron that sorb P. In such soils, cluster roots and other specialised roots that release P-mobilising carboxylates are more effective than mycorrhizas. Cluster roots are ephemeral structures that release carboxylates in an exudative burst. The carboxylates mobilise sparingly-available sources of soil P. The relative investment of biomass in cluster roots and the amount of carboxylates that are released during the exudative burst differ between species on severely weathered soils with a low total P concentration and species on young soils with high total P concentrations but low P availability. Taking a modelling approach, we explore how the optimal cluster-root strategy depends on soil characteristics, thus offering insights for plant breeders interested in developing crop plants with optimal cluster-root strategies.
AbstractList	•Mycorrhizas increase the volume of low-phosphorus soil that can be explored by roots.•Cluster roots release carboxylates, which mobilise sparingly available soil phosphorus.•Species with cluster roots are common on soils with a low phosphorus availability.•Phosphorus availability may be low because total soil phosphorus concentrations are low.•Phosphorus availability may also be low because the soil phosphorus is sorbed onto soil particles. Mycorrhizas play a pivotal role in phosphorus (P) acquisition of plant roots, by enhancing the soil volume that can be explored. Non-mycorrhizal plant species typically occur either in relatively fertile soil or on soil with a very low P availability, where there is insufficient P in the soil solution for mycorrhizal hyphae to be effective. Soils with a very low P availability are either old and severely weathered or relatively young with high concentrations of oxides and hydroxides of aluminium and iron that sorb P. In such soils, cluster roots and other specialised roots that release P-mobilising carboxylates are more effective than mycorrhizas. Cluster roots are ephemeral structures that release carboxylates in an exudative burst. The carboxylates mobilise sparingly-available sources of soil P. The relative investment of biomass in cluster roots and the amount of carboxylates that are released during the exudative burst differ between species on severely weathered soils with a low total P concentration and species on young soils with high total P concentrations but low P availability. Taking a modelling approach, we explore how the optimal cluster-root strategy depends on soil characteristics, thus offering insights for plant breeders interested in developing crop plants with optimal cluster-root strategies. Mycorrhizas play a pivotal role in phosphorus (P) acquisition of plant roots, by enhancing the soil volume that can be explored. Non-mycorrhizal plant species typically occur either in relatively fertile soil or on soil with a very low P availability, where there is insufficient P in the soil solution for mycorrhizal hyphae to be effective. Soils with a very low P availability are either old and severely weathered or relatively young with high concentrations of oxides and hydroxides of aluminium and iron that sorb P. In such soils, cluster roots and other specialised roots that release P-mobilising carboxylates are more effective than mycorrhizas. Cluster roots are ephemeral structures that release carboxylates in an exudative burst. The carboxylates mobilise sparingly-available sources of soil P. The relative investment of biomass in cluster roots and the amount of carboxylates that are released during the exudative burst differ between species on severely weathered soils with a low total P concentration and species on young soils with high total P concentrations but low P availability. Taking a modelling approach, we explore how the optimal cluster-root strategy depends on soil characteristics, thus offering insights for plant breeders interested in developing crop plants with optimal cluster-root strategies. Mycorrhizas play a pivotal role in phosphorus (P) acquisition of plant roots, by enhancing the soil volume that can be explored. Non-mycorrhizal plant species typically occur either in relatively fertile soil or on soil with a very low P availability, where there is insufficient P in the soil solution for mycorrhizal hyphae to be effective. Soils with a very low P availability are either old and severely weathered or relatively young with high concentrations of oxides and hydroxides of aluminium and iron that sorb P. In such soils, cluster roots and other specialised roots that release P-mobilising carboxylates are more effective than mycorrhizas. Cluster roots are ephemeral structures that release carboxylates in an exudative burst. The carboxylates mobilise sparingly-available sources of soil P. The relative investment of biomass in cluster roots and the amount of carboxylates that are released during the exudative burst differ between species on severely weathered soils with a low total P concentration and species on young soils with high total P concentrations but low P availability. Taking a modelling approach, we explore how the optimal cluster-root strategy depends on soil characteristics, thus offering insights for plant breeders interested in developing crop plants with optimal cluster-root strategies.Mycorrhizas play a pivotal role in phosphorus (P) acquisition of plant roots, by enhancing the soil volume that can be explored. Non-mycorrhizal plant species typically occur either in relatively fertile soil or on soil with a very low P availability, where there is insufficient P in the soil solution for mycorrhizal hyphae to be effective. Soils with a very low P availability are either old and severely weathered or relatively young with high concentrations of oxides and hydroxides of aluminium and iron that sorb P. In such soils, cluster roots and other specialised roots that release P-mobilising carboxylates are more effective than mycorrhizas. Cluster roots are ephemeral structures that release carboxylates in an exudative burst. The carboxylates mobilise sparingly-available sources of soil P. The relative investment of biomass in cluster roots and the amount of carboxylates that are released during the exudative burst differ between species on severely weathered soils with a low total P concentration and species on young soils with high total P concentrations but low P availability. Taking a modelling approach, we explore how the optimal cluster-root strategy depends on soil characteristics, thus offering insights for plant breeders interested in developing crop plants with optimal cluster-root strategies.
Author	Martinoia, Enrico Lambers, Hans Renton, Michael
Author_xml	– sequence: 1 givenname: Hans orcidid: 0000-0002-4118-2272 surname: Lambers fullname: Lambers, Hans email: hans.lambers@uwa.edu.au organization: School of Plant Biology and Institute of Agriculture, The University of Western Australia, 35 Stirling Highway, Crawley (Perth), Western Australia 6009, Australia – sequence: 2 givenname: Enrico surname: Martinoia fullname: Martinoia, Enrico organization: Institute of Plant Biology, University of Zurich, Zollikerstrasse 107, CH-8008 Zürich, Switzerland – sequence: 3 givenname: Michael surname: Renton fullname: Renton, Michael organization: School of Plant Biology and Institute of Agriculture, The University of Western Australia, 35 Stirling Highway, Crawley (Perth), Western Australia 6009, Australia
BackLink	https://www.ncbi.nlm.nih.gov/pubmed/25912783$$D View this record in MEDLINE/PubMed
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Snippet	•Mycorrhizas increase the volume of low-phosphorus soil that can be explored by roots.•Cluster roots release carboxylates, which mobilise sparingly available... Mycorrhizas play a pivotal role in phosphorus (P) acquisition of plant roots, by enhancing the soil volume that can be explored. Non-mycorrhizal plant species...
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SubjectTerms	Adaptation, Physiological aluminum biomass Carboxylic Acids - metabolism crops hydroxides hyphae iron mycorrhizae Mycorrhizae - physiology oxides phosphorus Phosphorus - metabolism plant breeders Plant Physiological Phenomena Plant Roots - metabolism Plant Roots - microbiology Plants - metabolism Plants - microbiology roots soil Soil - chemistry soil solution
Title	Plant adaptations to severely phosphorus-impoverished soils
URI	https://dx.doi.org/10.1016/j.pbi.2015.04.002 https://www.ncbi.nlm.nih.gov/pubmed/25912783 https://www.proquest.com/docview/1703239720 https://www.proquest.com/docview/2000153424
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