Location: root architecture structures rhizosphere microbial associations

• Published in: Journal of experimental botany Vol. 75; no. 2; pp. 594 - 604
• Main Authors: Galindo-Castañeda, Tania, Hartmann, Martin, Lynch, Jonathan P
• Format: Journal Article
• Language: English
• Published: UK Oxford University Press 10.01.2024
• Subjects: botany; Expert Views; exudation; microbiome; Plant Breeding; Plant Roots - metabolism; Rhizosphere; root systems; soil; Soil - chemistry; Soil Microbiology; soil vertical gradients; number of axial roots; rooting depth; Carbon rhizodeposition; rhizosphere microbiome; soil redox potential; lateral roots; root system architecture; root growth angle
• ISSN: 0022-0957; 1460-2431; 1460-2431
• DOI: 10.1093/jxb/erad421

Abstract Root architectural phenotypes are promising targets for crop breeding, but root architectural effects on microbial associations in agricultural fields are not well understood. Architecture determines the location of microbial associations within root systems, which, when integrated with soil vertical gradients, determines the functions and the metabolic capability of rhizosphere microbial communities. We argue that variation in root architecture in crops has important implications for root exudation, microbial recruitment and function, and the decomposition and fate of root tissues and exudates. Recent research has shown that the root microbiome changes along root axes and among root classes, that root tips have a unique microbiome, and that root exudates change within the root system depending on soil physicochemical conditions. Although fresh exudates are produced in larger amounts in root tips, the rhizosphere of mature root segments also plays a role in influencing soil vertical gradients. We argue that more research is needed to understand specific root phenotypes that structure microbial associations and discuss candidate root phenotypes that may determine the location of microbial hotspots within root systems with relevance to agricultural systems. Root architecture and soil vertical gradients create a diverse set of physicochemical conditions in which rhizosphere microbes live; however, these scaffolds of soil microbial ecology are rarely studied.