A plasma membrane transporter coordinates phosphate reallocation and grain filling in cereals

Phosphate (Pi) is essential to plant growth and crop yield. However, it remains unknown how Pi homeostasis is maintained during cereal grain filling. Here, we identified a rice grain-filling-controlling PHO1-type Pi transporter, OsPHO1;2, through map-based cloning. Pi efflux activity and its localization to the plasma membrane of seed tissues implicated a specific role for OsPHO1;2 in Pi reallocation during grain filling. Indeed, Pi over-accumulated in developing seeds of the Ospho1;2 mutant, which inhibited the activity of ADP-glucose pyrophosphorylase (AGPase), important for starch synthesis, and the grain-filling defect was alleviated by overexpression of AGPase in Ospho1;2-mutant plants. A conserved function was recognized for the maize transporter ZmPHO1;2. Importantly, ectopic overexpression of OsPHO1;2 enhanced grain yield, especially under low-Pi conditions. Collectively, we discovered a mechanism underlying Pi transport, grain filling and P-use efficiency, providing an efficient strategy for improving grain yield with minimal P-fertilizer input in cereals. A plasma membrane transporter OsPHO1;2 coordinates phosphate reallocation essential for starch biosynthesis during grain filling of cereal crops, providing a potential breeding target for improving phosphate-use efficiency.

Automated summary

The plasma membrane transporter OsPHO1;2 plays a crucial role in coordinating phosphate reallocation for starch biosynthesis during grain filling in cereal crops. Its mutation leads to excessive accumulation of Pi in developing seeds, inhibiting AGPase activity, and ultimately affecting grain filling. However, overexpression of AGPase can alleviate this defect. The maize transporter ZmPHO1;2 also functions similarly.