Root angle, phosphorus, and water: Interactions and effects on durum wheat genotype performance in drought-prone environments

Research output: Contribution to journalJournal articleResearchpeer-review

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Root angle, phosphorus, and water : Interactions and effects on durum wheat genotype performance in drought-prone environments. / van der Bom, Frederik J.T.; Williams, Alwyn; Raymond, Nelly S.; Alahmad, Samir; Hickey, Lee T.; Singh, Vijaya; Bell, Michael J.

In: Plant and Soil, 2024.

Research output: Contribution to journalJournal articleResearchpeer-review

Harvard

van der Bom, FJT, Williams, A, Raymond, NS, Alahmad, S, Hickey, LT, Singh, V & Bell, MJ 2024, 'Root angle, phosphorus, and water: Interactions and effects on durum wheat genotype performance in drought-prone environments', Plant and Soil. https://doi.org/10.1007/s11104-023-05966-z

APA

van der Bom, F. J. T., Williams, A., Raymond, N. S., Alahmad, S., Hickey, L. T., Singh, V., & Bell, M. J. (2024). Root angle, phosphorus, and water: Interactions and effects on durum wheat genotype performance in drought-prone environments. Plant and Soil. https://doi.org/10.1007/s11104-023-05966-z

Vancouver

van der Bom FJT, Williams A, Raymond NS, Alahmad S, Hickey LT, Singh V et al. Root angle, phosphorus, and water: Interactions and effects on durum wheat genotype performance in drought-prone environments. Plant and Soil. 2024. https://doi.org/10.1007/s11104-023-05966-z

Author

van der Bom, Frederik J.T. ; Williams, Alwyn ; Raymond, Nelly S. ; Alahmad, Samir ; Hickey, Lee T. ; Singh, Vijaya ; Bell, Michael J. / Root angle, phosphorus, and water : Interactions and effects on durum wheat genotype performance in drought-prone environments. In: Plant and Soil. 2024.

Bibtex

@article{da6da205e2364519ba6bdfe1d0fc5e73,
title = "Root angle, phosphorus, and water: Interactions and effects on durum wheat genotype performance in drought-prone environments",
abstract = "Purpose: Selection for root traits has become a target in (pre-)breeding programs aiming at improving crop ability to capture soil resources. However, the benefit of selected traits in heterogeneous target environments will depend on spatial and temporal interactions between root systems, the soil environment (fertility and water supply) and management (fertiliser placement). Methods: We assessed growth and phosphorus acquisition of durum wheat (Triticum durum L.) lines defined by contrasting seminal root angles (41° {\textquoteleft}Narrow{\textquoteright} vs 82° {\textquoteleft}Wide{\textquoteright}), in response to different soil phosphorus placements and seasonal water dynamics. Responses were evaluated in clear pots (seedlings), rhizoboxes (late-tillering stage) and a custom lysimeter system (flowering stage). Results: The Narrow genotype increased deep soil exploration (down to 50 cm) during early growth, with a tendency to more rapidly acquire phosphorus placed as a deep fertiliser band (25 cm depth). However, genotypic differences in shoot biomass or phosphorus uptake were not apparent at anthesis, in part due to phosphorus-induced changes in phenological development. Contrastingly, the wide genotype increased root growth in the topsoil (0–10 cm) when phosphorus was stratified in this layer and produced greater biomass at anthesis under these conditions. Shoot and root biomass and phosphorus uptake decreased when the topsoil dried out, with the greatest effect observed for phosphorus stratified in this layer. Conclusion: The benefits of the selected root angle trait strongly depend on nutrient and water distributions and dynamics in the target environment. Ideotype breeding efforts and farmer selection of genotypes should consider the context in which genotypes will be deployed. Highlight: The interaction between root system architecture and heterogeneous distributions of phosphorus and available water determine the relative performance of durum wheat genotypes with contrasting root angles.",
keywords = "Drought, G × E × M interactions, Phosphorus stratification, Root angle, Root distribution, Root ideotypes, Root morphology, Root proliferation, Rooting depth, Soil heterogeneity",
author = "{van der Bom}, {Frederik J.T.} and Alwyn Williams and Raymond, {Nelly S.} and Samir Alahmad and Hickey, {Lee T.} and Vijaya Singh and Bell, {Michael J.}",
note = "Publisher Copyright: {\textcopyright} 2023, The Author(s).",
year = "2024",
doi = "10.1007/s11104-023-05966-z",
language = "English",
journal = "Plant and Soil",
issn = "0032-079X",
publisher = "Springer",

}

RIS

TY - JOUR

T1 - Root angle, phosphorus, and water

T2 - Interactions and effects on durum wheat genotype performance in drought-prone environments

AU - van der Bom, Frederik J.T.

AU - Williams, Alwyn

AU - Raymond, Nelly S.

AU - Alahmad, Samir

AU - Hickey, Lee T.

AU - Singh, Vijaya

AU - Bell, Michael J.

N1 - Publisher Copyright: © 2023, The Author(s).

PY - 2024

Y1 - 2024

N2 - Purpose: Selection for root traits has become a target in (pre-)breeding programs aiming at improving crop ability to capture soil resources. However, the benefit of selected traits in heterogeneous target environments will depend on spatial and temporal interactions between root systems, the soil environment (fertility and water supply) and management (fertiliser placement). Methods: We assessed growth and phosphorus acquisition of durum wheat (Triticum durum L.) lines defined by contrasting seminal root angles (41° ‘Narrow’ vs 82° ‘Wide’), in response to different soil phosphorus placements and seasonal water dynamics. Responses were evaluated in clear pots (seedlings), rhizoboxes (late-tillering stage) and a custom lysimeter system (flowering stage). Results: The Narrow genotype increased deep soil exploration (down to 50 cm) during early growth, with a tendency to more rapidly acquire phosphorus placed as a deep fertiliser band (25 cm depth). However, genotypic differences in shoot biomass or phosphorus uptake were not apparent at anthesis, in part due to phosphorus-induced changes in phenological development. Contrastingly, the wide genotype increased root growth in the topsoil (0–10 cm) when phosphorus was stratified in this layer and produced greater biomass at anthesis under these conditions. Shoot and root biomass and phosphorus uptake decreased when the topsoil dried out, with the greatest effect observed for phosphorus stratified in this layer. Conclusion: The benefits of the selected root angle trait strongly depend on nutrient and water distributions and dynamics in the target environment. Ideotype breeding efforts and farmer selection of genotypes should consider the context in which genotypes will be deployed. Highlight: The interaction between root system architecture and heterogeneous distributions of phosphorus and available water determine the relative performance of durum wheat genotypes with contrasting root angles.

AB - Purpose: Selection for root traits has become a target in (pre-)breeding programs aiming at improving crop ability to capture soil resources. However, the benefit of selected traits in heterogeneous target environments will depend on spatial and temporal interactions between root systems, the soil environment (fertility and water supply) and management (fertiliser placement). Methods: We assessed growth and phosphorus acquisition of durum wheat (Triticum durum L.) lines defined by contrasting seminal root angles (41° ‘Narrow’ vs 82° ‘Wide’), in response to different soil phosphorus placements and seasonal water dynamics. Responses were evaluated in clear pots (seedlings), rhizoboxes (late-tillering stage) and a custom lysimeter system (flowering stage). Results: The Narrow genotype increased deep soil exploration (down to 50 cm) during early growth, with a tendency to more rapidly acquire phosphorus placed as a deep fertiliser band (25 cm depth). However, genotypic differences in shoot biomass or phosphorus uptake were not apparent at anthesis, in part due to phosphorus-induced changes in phenological development. Contrastingly, the wide genotype increased root growth in the topsoil (0–10 cm) when phosphorus was stratified in this layer and produced greater biomass at anthesis under these conditions. Shoot and root biomass and phosphorus uptake decreased when the topsoil dried out, with the greatest effect observed for phosphorus stratified in this layer. Conclusion: The benefits of the selected root angle trait strongly depend on nutrient and water distributions and dynamics in the target environment. Ideotype breeding efforts and farmer selection of genotypes should consider the context in which genotypes will be deployed. Highlight: The interaction between root system architecture and heterogeneous distributions of phosphorus and available water determine the relative performance of durum wheat genotypes with contrasting root angles.

KW - Drought

KW - G × E × M interactions

KW - Phosphorus stratification

KW - Root angle

KW - Root distribution

KW - Root ideotypes

KW - Root morphology

KW - Root proliferation

KW - Rooting depth

KW - Soil heterogeneity

U2 - 10.1007/s11104-023-05966-z

DO - 10.1007/s11104-023-05966-z

M3 - Journal article

AN - SCOPUS:85150014899

JO - Plant and Soil

JF - Plant and Soil

SN - 0032-079X

ER -

ID: 340805856