The OsWRKY72–OsAAT30/OsGSTU26 module mediates reactive oxygen species scavenging to drive heterosis for salt tolerance in hybrid rice

ABSTRACT Hybrid rice (Oryza sativa) generally outperforms its inbred parents in yield and stress tolerance, a phenomenon termed heterosis, but the underlying mechanism is not completely understood. Here, we combined transcriptome, proteome, physiological, and heterosis analyses to examine the salt response of super hybrid rice Chaoyou1000 (CY1000). In addition to surpassing the mean values for its two parents (mid‐parent heterosis), CY1000 exhibited a higher reactive oxygen species scavenging ability than both its parents (over‐parent heterosis or heterobeltiosis). Nonadditive expression and allele‐specific gene expression assays showed that the glutathione S‐transferase gene OsGSTU26 and the amino acid transporter gene OsAAT30 may have major roles in heterosis for salt tolerance, acting in an overdominant fashion in CY1000. Furthermore, we identified OsWRKY72 as a common transcription factor that binds and regulates OsGSTU26 and OsAAT30. The salt‐sensitive phenotypes were associated with the OsWRKY72paternal genotype or the OsAAT30maternal genotype in core rice germplasm varieties. OsWRKY72paternal specifically repressed the expression of OsGSTU26 under salt stress, leading to salinity sensitivity, while OsWRKY72maternal specifically repressed OsAAT30, resulting in salinity tolerance. These results suggest that the OsWRKY72–OsAAT30/OsGSTU26 module may play an important role in heterosis for salt tolerance in an overdominant fashion in CY1000 hybrid rice, providing valuable clues to elucidate the mechanism of heterosis for salinity tolerance in hybrid rice. The glutathione S‐transferase gene OsGSTU26 and the amino acid transporter gene OsAAT30, the major genes for heterosis in salinity tolerance, act in an overdominant fashion in hybrid rice CY1000. OsWRKY72 regulates reactive oxygen species scavenging under salt stress by repressing their expression, thus mediating heterobeltiosis for salinity tolerance.