RootSlice—A novel functional‐structural model for root anatomical phenotypes

• Published in: Plant, cell and environment Vol. 46; no. 5; pp. 1671 - 1690
• Main Authors: Sidhu, Jagdeep Singh, Ajmera, Ishan, Arya, Sankalp, Lynch, Jonathan P.
• Format: Journal Article
• Language: English
• Published: United States Wiley Subscription Services, Inc 01.05.2023; Wiley
• Subjects: Anatomy; BASIC BIOLOGICAL SCIENCES; Corn; cortical cell files; Elongation; functional-structural modelling; Metabolism; multicellular model; multiscale model integration; Nitrogen - metabolism; OpenSimRoot; phene interactions; Phenotype; Phenotypes; Plant Roots - metabolism; Plant species; rhizoeconomics; root anatomy; root cortical aerenchyma; Roots; Soil; Soils; Structural models; Structure-function relationships; vacuole size; Zea mays - metabolism; OpenSimRoot; phene interactions; root cortical aerenchyma; cortical cell files; functional-structural modelling; rhizoeconomics; vacuole size; multiscale model integration; root anatomy; multicellular model
• ISSN: 0140-7791; 1365-3040; 1365-3040
• DOI: 10.1111/pce.14552

Root anatomy is an important determinant of root metabolic costs, soil exploration, and soil resource capture. Root anatomy varies substantially within and among plant species. RootSlice is a multicellular functional‐structural model of root anatomy developed to facilitate the analysis and understanding of root anatomical phenotypes. RootSlice can capture phenotypically accurate root anatomy in three dimensions of different root classes and developmental zones, of both monocotyledonous and dicotyledonous species. Several case studies are presented illustrating the capabilities of the model. For maize nodal roots, the model illustrated the role of vacuole expansion in cell elongation; and confirmed the individual and synergistic role of increasing root cortical aerenchyma and reducing the number of cortical cell files in reducing root metabolic costs. Integration of RootSlice for different root zones as the temporal properties of the nodal roots in the whole‐plant and soil model OpenSimRoot/maize enabled the multiscale evaluation of root anatomical phenotypes, highlighting the role of aerenchyma formation in enhancing the utility of cortical cell files for improving plant performance over varying soil nitrogen supply. Such integrative in silico approaches present avenues for exploring the fitness landscape of root anatomical phenotypes. Summary statement Root anatomy remains an underutilized target for crop breeding. RootSlice, a multicellular functional‐structural model of root anatomy, simulates the costs and benefits of diverse root anatomical phenotypes to estimate their utility for plant fitness in unfavourable soil environments.