Litcius/Paper detail

Multiple Integrated Root Phenotypes Are Associated with Improved Drought Tolerance

Stephanie P. Klein, Hannah Schneider, Alden Perkins, Kathleen M. Brown, Jonathan P. Lynch

2020PLANT PHYSIOLOGY149 citationsDOIOpen Access PDF

Abstract

) genotypes under well-watered and water-stressed conditions in the field. We found substantial variation in all 23 root phenes measured. A phenotypic bulked segregant analysis revealed that bulks representing the best and worst performers in the field displayed distinct root phenotypes. In contrast to the worst bulk, the root phenotype of the best bulk under drought consisted of greater cortical aerenchyma formation, more numerous and narrower metaxylem vessels, and thicker nodal roots. Partition-against-medians clustering revealed several clusters of unique root phenotypes related to plant performance under water stress. Clusters associated with improved drought tolerance consisted of phene states that likely enable greater soil exploration by reallocating internal resources to greater root construction (increased aerenchyma content, larger cortical cells, fewer cortical cell files), restrict uptake of water to conserve soil moisture (reduced hydraulic conductance, narrow metaxylem vessels), and improve penetrability of hard, dry soils (thick roots with a larger proportion of stele, and smaller distal cortical cells). We propose that the most drought-tolerant-integrated phenotypes merit consideration as breeding ideotypes.

Topics & Concepts

SteleAerenchymaBiologyDrought tolerancePhenotypeSoil waterXylemWater contentBotanyAgronomyHorticultureEcologyGeneticsGeneGeotechnical engineeringEngineeringPlant nutrient uptake and metabolismPlant responses to water stressPlant Molecular Biology Research