| Literature DB >> 33833418 |
Peng Yu1,2,3, Xiaoming He1,2,3, Marcel Baer2, Stien Beirinckx4,5,6, Tian Tian7, Yudelsy A T Moya8, Xuechen Zhang9, Marion Deichmann10, Felix P Frey2, Verena Bresgen2,3, Chunjian Li11, Bahar S Razavi12, Gabriel Schaaf10, Nicolaus von Wirén8, Zhen Su7, Marcel Bucher13,14, Kenichi Tsuda15,16, Sofie Goormachtig4,6, Xinping Chen17, Frank Hochholdinger18,19.
Abstract
Beneficial interactions between plant roots and rhizosphere microorganisms are pivotal for plant fitness. Nevertheless, the molecular mechanisms controlling the feedback between root architecture and microbial community structure remain elusive in maize. Here, we demonstrate that transcriptomic gradients along the longitudinal root axis associate with specific shifts in rhizosphere microbial diversity. Moreover, we have established that root-derived flavones predominantly promote the enrichment of bacteria of the taxa Oxalobacteraceae in the rhizosphere, which in turn promote maize growth and nitrogen acquisition. Genetic experiments demonstrate that LRT1-mediated lateral root development coordinates the interactions of the root system with flavone-dependent Oxalobacteraceae under nitrogen deprivation. In summary, these experiments reveal the genetic basis of the reciprocal interactions between root architecture and the composition and diversity of specific microbial taxa in the rhizosphere resulting in improved plant performance. These findings may open new avenues towards the breeding of high-yielding and nutrient-efficient crops by exploiting their interaction with beneficial soil microorganisms.Entities:
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Year: 2021 PMID: 33833418 DOI: 10.1038/s41477-021-00897-y
Source DB: PubMed Journal: Nat Plants ISSN: 2055-0278 Impact factor: 15.793