Harini Rangarajan1, Johannes A Postma2, Jonathan P Lynch1. 1. Department of Plant Science, The Pennsylvania State University, Tyson Building, University Park, PA, USA. 2. IBG2, Forschungszentrum Jülich, Jülich, Germany.
Abstract
Background and Aims: Root architecture is a primary determinant of soil resource acquisition. We hypothesized that root architectural phenes will display both positive and negative interactions with each other for soil resource capture because of competition for internal resources and functional trade-offs in soil exploration. Methods: We employed the functional-structural plant model SimRoot to explore how interactions among architectural phenes in common bean determine the acquisition of phosphate and nitrate, two key soil resources contrasting in mobility. We evaluated the utility of basal root whorl number (BRWN) when basal root growth angle, hypocotyl-borne roots and lateral root branching density (LRBD) were varied, under varying availability of phosphate and nitrate. Key Results: Three basal root whorls were optimal in most phenotypes. This optimum shifted towards greater values when LRBD decreased and to smaller numbers when LRBD increased. The maximum biomass accumulated for a given BRWN phenotype in a given limiting nutrient scenario depended upon root growth angle. Under phosphorus stress shallow phenotypes grew best, whereas under nitrate stress fanned phenotypes grew best. The effect of increased hypocotyl-borne roots depended upon BRWN as well as the limiting nutrient. Greater production of axial roots due to BRWN or hypocotyl-borne roots reduced rooting depth, leading to reduced biomass under nitrate-limiting conditions. Increased BRWN as well as greater LRBD increased root carbon consumption, resulting in reduced shoot biomass. Conclusions: We conclude that the utility of a root architectural phenotype is determined by whether the constituent phenes are synergistic or antagonistic. Competition for internal resources and trade-offs for external resources result in multiple phenotypes being optimal under a given nutrient regime. We also find that no single phenotype is optimal across contrasting environments. These results have implications for understanding plant evolution and also for the breeding of more stress-tolerant crop phenotypes.
Background and Aims: Root architecture is a primary determinant of soil resource acquisition. We hypothesized that root architectural phenes will display both positive and negative interactions with each other for soil resource capture because of competition for internal resources and functional trade-offs in soil exploration. Methods: We employed the functional-structural plant model SimRoot to explore how interactions among architectural phenes in common bean determine the acquisition of phosphate and nitrate, two key soil resources contrasting in mobility. We evaluated the utility of basal root whorl number (BRWN) when basal root growth angle, hypocotyl-borne roots and lateral root branching density (LRBD) were varied, under varying availability of phosphate and nitrate. Key Results: Three basal root whorls were optimal in most phenotypes. This optimum shifted towards greater values when LRBD decreased and to smaller numbers when LRBD increased. The maximum biomass accumulated for a given BRWN phenotype in a given limiting nutrient scenario depended upon root growth angle. Under phosphorus stress shallow phenotypes grew best, whereas under nitrate stress fanned phenotypes grew best. The effect of increased hypocotyl-borne roots depended upon BRWN as well as the limiting nutrient. Greater production of axial roots due to BRWN or hypocotyl-borne roots reduced rooting depth, leading to reduced biomass under nitrate-limiting conditions. Increased BRWN as well as greater LRBD increased root carbon consumption, resulting in reduced shoot biomass. Conclusions: We conclude that the utility of a root architectural phenotype is determined by whether the constituent phenes are synergistic or antagonistic. Competition for internal resources and trade-offs for external resources result in multiple phenotypes being optimal under a given nutrient regime. We also find that no single phenotype is optimal across contrasting environments. These results have implications for understanding plant evolution and also for the breeding of more stress-tolerant crop phenotypes.
Authors: Patompong Saengwilai; Eric A Nord; Joseph G Chimungu; Kathleen M Brown; Jonathan Paul Lynch Journal: Plant Physiol Date: 2014-06-02 Impact factor: 8.340
Authors: Pieterjan De Bauw; Trung Hieu Mai; Andrea Schnepf; Roel Merckx; Erik Smolders; Jan Vanderborght Journal: Ann Bot Date: 2020-09-14 Impact factor: 4.357
Authors: Stephanie P Klein; Hannah M Schneider; Alden C Perkins; Kathleen M Brown; Jonathan P Lynch Journal: Plant Physiol Date: 2020-04-24 Impact factor: 8.340
Authors: Li Wang; Tao Zhou; Bin Cheng; Yongli Du; Sisi Qin; Yang Gao; Mei Xu; Junji Lu; Ting Liu; Shuxian Li; Weiguo Liu; Wenyu Yang Journal: Plants (Basel) Date: 2020-09-15
Authors: Hannah M Schneider; Stephanie P Klein; Meredith T Hanlon; Eric A Nord; Shawn Kaeppler; Kathleen M Brown; Andrew Warry; Rahul Bhosale; Jonathan P Lynch Journal: J Exp Bot Date: 2020-05-30 Impact factor: 6.992
Authors: J Vladimir Torres-Rodríguez; M Nancy Salazar-Vidal; Ricardo A Chávez Montes; Julio A Massange-Sánchez; C Stewart Gillmor; Ruairidh J H Sawers Journal: BMC Plant Biol Date: 2021-06-05 Impact factor: 4.215