Current Plant Biology (Jun 2024)

Enhancement of rice traits for the maintenance of the phosphorus balance between rice plants and the soil

  • Ian Paul Navea,
  • Shiyi Yang,
  • Priskila Tolangi,
  • Raña Mae Sumabat,
  • Wenhua Zhang,
  • Joong Hyoun Chin

Journal volume & issue
Vol. 38
p. 100332

Abstract

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Phosphorus (P) is essential for maximizing crop yield, yet many areas dedicated to rice cultivation suffer from a scarcity of plant-accessible inorganic phosphate (Pi) due to its fixation in the soil. Conversely, regions with ample P fertilization often resort to excessive application to compensate for deficiencies, resulting in adverse environmental impacts. While significant strides have been made in understanding the molecular mechanisms governing P uptake capacity (PUP/PAE) and P use efficiency (PUE) in rice, their practical implementation in breeding is impeded by the absence of robust, high throughput phenomics techniques, leading to inconsistencies in gene/quantitative trait loci (QTL) effects. This review underscores the necessity for a comprehensive understanding of Pi transporters, internal Pi remobilization, and root morphology modifications under Pi deficiency, correlating these traits with specific phenotypic markers. Developing precise, cost-effective, high-throughput phenotyping techniques is imperative for creating rice ideotypes with enhanced PAE/PUE. Additionally, we explore the potential of meta-QTL analysis in prioritizing genomic loci related to PUE, utilizing a “meta-genome” encompassing diverse rice reference genomes. We also delve into the potential in the development of phosphite (Phi)-tolerant rice, aiming to reduce dependence on P fertilizers and create herbicide-resistant rice through Phi-based fertilization. Finally, we discuss the utilization of arbuscular mycorrhizal fungi (AMF) to enhance P uptake in rice.

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