Reduction in Root Secondary Growth as a Strategy for Phosphorus Acquisition

Strock, Christopher F.; Riva, Laurie Morrow De La; Lynch, Jonathan P.

doi:10.1104/pp.17.01583

Cited by 102 publications

(91 citation statements)

References 51 publications

(63 reference statements)

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“…These results have recently been supported by empirical results with maize, which show that genotypes with greater RCA formation have greater topsoil foraging, P capture, growth, and yield in low‐P soil than genotypes with less RCA, notwithstanding the reduction in mycorrhizal habitat by RCA formation (Galindo‐Castañeda et al ., ). In dicots, P stress inhibits the secondary growth of roots, and common bean genotypes with greater inhibition of secondary growth under P stress have reduced root costs, greater P capture, and greater growth in low‐P soil (Strock et al ., ; Fig. ).…”

Section: Phosphorusmentioning

confidence: 93%

“…Crop breeding for root architectural and anatomical phenotypes with better P capture could have important indirect consequences for AMS, however. For example, RCA formation, root cortical senescence, and reduced secondary growth all improve P capture, and all have important consequences for AMS by regulating the volume of AMS habitat in the root cortex (Galindo‐Castañeda et al ., ; Schneider & Lynch, ; Strock et al ., ). Architectural phenes that localize root foraging in shallow or deep soil domains may also affect AMS, since the propagules of fungal symbionts, as well as the foraging environments of extraradical hyphae, are more favorable in the topsoil (Lynch & Wojciechowski, ).…”

Section: Phosphorusmentioning

confidence: 97%

“…As already noted, anatomical phenotypes that reduce the metabolic cost of soil exploration improve the capture of P and N. They also improve the capture of water: increased RCA (Zhu et al ., ; Chimungu et al ., ), reduced cortical cell file number (Chimungu et al ., ), increased cortical cell size (Chimungu et al ., ), and possibly cortical senescence (Schneider & Lynch, ) improve water capture under drought. The reduction of mycorrhizal habitat in anatomical phenotypes that reduce cortical volume does not appear to counteract the major benefit that these phenotypes confer for soil exploration and P capture (Galindo‐Castañeda et al ., ; Strock et al ., ). RCA has the added benefit of improving root function under hypoxia, which is important for subsoil foraging (Lynch & Wojciechowski, ).…”

Section: Cross‐cutting Issuesmentioning

confidence: 97%

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Root phenotypes for improved nutrient capture: an underexploited opportunity for global agriculture

2019

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Summary Nutrient‐efficient crops are a solution to the two grand challenges of modern agriculture: improving food security while reducing environmental impacts. The primary challenges are (1) nitrogen (N) and phosphorus (P) efficiency; (2) potassium (K), calcium (Ca), and magnesium (Mg) efficiency for acid soils; and (3) iron (Fe) and zinc (Zn) efficiency for alkaline soils. Root phenotypes are promising breeding targets for each of these. The Topsoil Foraging ideotype is beneficial for P capture and should also be useful for capture of K, Ca, and Mg in acid soils. The Steep, Cheap, and Deep ideotype for subsoil foraging is beneficial for N and water capture. Fe and Zn capture can be improved by targeting mechanisms of metal mobilization in the rhizosphere. Root hairs and phenes that reduce the metabolic cost of soil exploration should be prioritized in breeding programs. Nutrient‐efficient crops should provide benefits at all input levels. Although our current understanding is sufficient to deploy root phenotypes for improved nutrient capture in crop breeding, this complex topic does not receive the resources it merits in either applied or basic plant biology. Renewed emphasis on these topics is needed in order to develop the nutrient‐efficient crops urgently needed in global agriculture.

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Section: Phosphorusmentioning

confidence: 93%

Section: Phosphorusmentioning

confidence: 97%

Section: Cross‐cutting Issuesmentioning

confidence: 97%

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Root phenotypes for improved nutrient capture: an underexploited opportunity for global agriculture

2019

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“…Currently, enhanced carbohydrate transport to the root has been demonstrated for nitrogen (N) and phosphorus (P) limitation (Hermans et al ). In the case of P limitation in common bean ( Phaseolus vulgaris ), it has been recently confirmed that secondary root growth is impaired in favor of root elongation, thus optimizing P acquisition under low P conditions (Strock et al ). This preferential C investment in primary root growth was also reported for Arabidopsis submitted to low Pi (Hanlon et al ).…”

Section: Root Sugar Transport In Response To Abiotic Factorsmentioning

confidence: 99%

Sugars en route to the roots. Transport, metabolism and storage within plant roots and towards microorganisms of the rhizosphere

Hennion

Durand

Vriet

et al. 2018

Physiologia Plantarum

106

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In plants, the root is a typical sink organ that relies exclusively on the import of sugar from the aerial parts. Sucrose is delivered by the phloem to the most distant root tips and, en route to the tip, is used by the different root tissues for metabolism and storage. Besides, a certain portion of this carbon is exuded in the rhizosphere, supplied to beneficial microorganisms and diverted by parasitic microbes. The transport of sugars toward these numerous sinks either occurs symplastically through cell connections (plasmodesmata) or is apoplastically mediated through membrane transporters (MST, mononsaccharide tranporters, SUT/SUC, H+/sucrose transporters and SWEET, Sugar will eventually be exported transporters) that control monosaccharide and sucrose fluxes. Here, we review recent progresses on carbon partitioning within and outside roots, discussing membrane transporters involved in plant responses to biotic and abiotic factors.

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“…Lynch () and Strock et al . () have reported that smaller root cross‐sectional area induced by plants adaptive response of decreased root secondary growth increases root length (for greater soil exploration) and improves the consumption of growth‐limiting resources. Growth allometry is induced by multiple cryptic genetic factors associated with local climate and abiotic stress response (Vasseur et al ., ), suggesting that the contrasting response of tiller and main‐shoot nodal roots may be an adaptive response to water deficit.…”

Section: Discussionmentioning

confidence: 99%

Genetic components of root architecture and anatomy adjustments to water‐deficit stress in spring barley

Oyiga

Palczak

Wojciechowski

et al. 2019

Plant Cell & Environment

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Roots perform vital roles for adaptation and productivity under water‐deficit stress, even though their specific functions are poorly understood. In this study, the genetic control of the nodal‐root architectural and anatomical response to water deficit were investigated among diverse spring barley accessions. Water deficit induced substantial variations in the nodal root traits. The cortical, stele, and total root cross‐sectional areas of the main‐shoot nodal roots decreased under water deficit, but increased in the tiller nodal roots. Root xylem density and arrested nodal roots increased under water deficit, with the formation of root suberization/lignification and large cortical aerenchyma. Genome‐wide association study implicated 11 QTL intervals in the architectural and anatomical nodal root response to water deficit. Among them, three and four QTL intervals had strong effects across seasons and on both root architectural and anatomical traits, respectively. Genome‐wide epistasis analysis revealed 44 epistatically interacting SNP loci. Further analyses showed that these QTL intervals contain important candidate genes, including ZIFL2, MATE, and PPIB, whose functions are shown to be related to the root adaptive response to water deprivation in plants. These results give novel insight into the genetic architectures of barley nodal root response to soil water deficit stress in the fields, and thus offer useful resources for root‐targeted marker‐assisted selection.

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Reduction in Root Secondary Growth as a Strategy for Phosphorus Acquisition

Cited by 102 publications

References 51 publications

Root phenotypes for improved nutrient capture: an underexploited opportunity for global agriculture

Root phenotypes for improved nutrient capture: an underexploited opportunity for global agriculture

Sugars en route to the roots. Transport, metabolism and storage within plant roots and towards microorganisms of the rhizosphere

Genetic components of root architecture and anatomy adjustments to water‐deficit stress in spring barley

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