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Dosage differences in 12-OXOPHYTODIENOATE REDUCTASE genes modulate wheat root growth.
- Gabay, Gilad;
- Wang, Hanchao;
- Zhang, Junli;
- Moriconi, Jorge I;
- Burguener, German F;
- Gualano, Leonardo D;
- Howell, Tyson;
- Lukaszewski, Adam;
- Staskawicz, Brian;
- Cho, Myeong-Je;
- Tanaka, Jaclyn;
- Fahima, Tzion;
- Ke, Haiyan;
- Dehesh, Katayoon;
- Zhang, Guo-Liang;
- Gou, Jin-Ying;
- Hamberg, Mats;
- Santa-María, Guillermo E;
- Dubcovsky, Jorge
- et al.
Abstract
Wheat, an essential crop for global food security, is well adapted to a wide variety of soils. However, the gene networks shaping different root architectures remain poorly understood. We report here that dosage differences in a cluster of monocot-specific 12-OXOPHYTODIENOATE REDUCTASE genes from subfamily III (OPRIII) modulate key differences in wheat root architecture, which are associated with grain yield under water-limited conditions. Wheat plants with loss-of-function mutations in OPRIII show longer seminal roots, whereas increased OPRIII dosage or transgenic over-expression result in reduced seminal root growth, precocious development of lateral roots and increased jasmonic acid (JA and JA-Ile). Pharmacological inhibition of JA-biosynthesis abolishes root length differences, consistent with a JA-mediated mechanism. Transcriptome analyses of transgenic and wild-type lines show significant enriched JA-biosynthetic and reactive oxygen species (ROS) pathways, which parallel changes in ROS distribution. OPRIII genes provide a useful entry point to engineer root architecture in wheat and other cereals.
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