Reduction in Root Secondary Growth as a Strategy for Phosphorus Acquisition

We tested the hypothesis that reduced root secondary growth of dicotyledonous species improves phosphorus acquisition. Functional-structural modeling in SimRoot indicates that, in common bean (Phaseolus vulgaris), reduced root secondary growth reduces root metabolic costs, increases root length, imp...

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Bibliographic Details
Published inPlant physiology (Bethesda) Vol. 176; no. 1; pp. 691 - 703
Main Authors Strock, Christopher F., de la Riva, Laurie Morrow, Lynch, Jonathan P.
Format Journal Article
LanguageEnglish
Published United States American Society of Plant Biologists 01.01.2018
Subjects
Biomass
Cell Respiration
Computer Simulation
ECOPHYSIOLOGY AND SUSTAINABILITY
Hyphae - physiology
Mycorrhizae - physiology
Phaseolus - growth & development
Phaseolus - metabolism
Phaseolus - physiology
Phenotype
Phosphorus - metabolism
Plant Development
Plant Leaves - anatomy & histology
Plant Roots - anatomy & histology
Plant Roots - growth & development
Plant Roots - metabolism
Plant Shoots - growth & development
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Summary:We tested the hypothesis that reduced root secondary growth of dicotyledonous species improves phosphorus acquisition. Functional-structural modeling in SimRoot indicates that, in common bean (Phaseolus vulgaris), reduced root secondary growth reduces root metabolic costs, increases root length, improves phosphorus capture, and increases shoot biomass in low-phosphorus soil. Observations from the field and greenhouse confirm that, under phosphorus stress, resource allocation is shifted from secondary to primary root growth, genetic variation exists for this response, and reduced secondary growth improves phosphorus capture from low-phosphorus soil. Under low phosphorus in greenhouse mesocosms, genotypes with reduced secondary growth had 39% smaller root cross-sectional area, 60% less root respiration, 27% greater root length, 78% greater shoot phosphorus content, and 68% greater shoot mass than genotypes with advanced secondary growth. In the field under low phosphorus, these genotypes had 43% smaller root cross-sectional area, 32% greater root length, 58% greater shoot phosphorus content, and 80% greater shoot mass than genotypes with advanced secondary growth. Secondary growth eliminated arbuscular mycorrhizal associations as cortical tissue was destroyed. These results support the hypothesis that reduced root secondary growth is an adaptive response to low phosphorus availability and merits investigation as a potential breeding target.
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www.plantphysiol.org/cgi/doi/10.1104/pp.17.01583
C.F.S. performed all of the experiments, analyzed the data, and wrote the article with contributions of all the authors; L.M.d.l.R. carried out the original screening and foundational research for these published data; J.P.L. conceived the hypotheses and supervised the design, experimentation, analysis, and reporting.
The author responsible for distribution of materials integral to the findings presented in this article in accordance with the policy described in the Instructions for Authors (www.plantphysiol.org) is: Jonathan P. Lynch (jpl4@psu.edu).
Current address: 221 Tyson Building, University Park, PA 16802.
ISSN:0032-0889
1532-2548
1532-2548
DOI:10.1104/pp.17.01583