Strigolactones regulate rice tiller angle by attenuating shoot gravitropism through inhibiting auxin biosynthesis

Tiller angle, a key agronomic trait for achieving ideal plant architecture and increasing grain yield, is regulated mainly by shoot gravitropism. Strigolactones (SLs) are a group of newly identified plant hormones that are essential for shoot branching/rice tillering and have further biological func...

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Bibliographic Details
Published in:Proceedings of the National Academy of Sciences - PNAS 2014-07, Vol.111 (30), p.11199-11204
Main Authors: Sang, Dajun, Chen, Dongqin, Liu, Guifu, Liang, Yan, Huang, Linzhou, Meng, Xiangbing, Chu, Jinfang, Sun, Xiaohong, Dong, Guojun, Yuan, Yundong, Qian, Qian, Li, Jiayang, Wang, Yonghong
Format: Article
Language:English
Subjects:
Auxins
Biological Sciences
Biological Transport, Active - physiology
Biosynthesis
Genotype & phenotype
Gravitropism
Gravitropism - physiology
Hormones
Indoleacetic Acids
Insulin antibodies
Mutation
Oryza - genetics
Oryza - metabolism
Plant growth regulators
Plant Growth Regulators - genetics
Plant Growth Regulators - metabolism
Plant Proteins - genetics
Plant Proteins - metabolism
Plant Shoots - genetics
Plant Shoots - metabolism
Plants
Repressor Proteins - genetics
Repressor Proteins - metabolism
Rice
Seedlings
Signal Transduction - physiology
Tillers
Transcriptional regulatory elements
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Summary:Tiller angle, a key agronomic trait for achieving ideal plant architecture and increasing grain yield, is regulated mainly by shoot gravitropism. Strigolactones (SLs) are a group of newly identified plant hormones that are essential for shoot branching/rice tillering and have further biological functions as yet undetermined. Through screening for suppressors of lazy1 (sols), a classic rice mutant exhibiting large tiller angle and defective shoot gravitropism, we identified multiple SOLS that are involved in the SL biosynthetic or signaling pathway. We show that SL biosynthetic or signaling mutants can rescue the spreading phenotype of lazy1 (la1) and that SLs can inhibit auxin biosynthesis and attenuate rice shoot gravitropism, mainly by decreasing the local indoleacetic acid content. Although both SLs and LA1 are negative regulators of polar auxin transport, SLs do not alter the lateral auxin transport of shoot base, unlike LA1 , which is a positive regulator of lateral auxin transport in rice. Genetic evidence demonstrates that SLs and LA1 participate in regulating shoot gravitropism and tiller angle in distinct genetic pathways. In addition, the SL-mediated shoot gravitropism is conserved in Arabidopsis . Our results disclose a new role of SLs and shed light on a previously unidentified mechanism underlying shoot gravitropism. Our study indicates that SLs could be considered as an important tool to achieve ideal plant architecture in the future.
ISSN:0027-8424
1091-6490
DOI:10.1073/pnas.1411859111