Wild rice Oryza rufipogon, a progenitor of cultivated rice Oryza sativa L., possesses superior salinity tolerance and is a potential donor for breeding salinity tolerance traits in rice. However, a mechanistic basis of salinity tolerance in this donor species has not been established. Here, we examined salinity tolerance from the early vegetative stage to maturity in O. rufipogon in comparison with a salt-susceptible (Koshihikari) and a salt-tolerant (Reiziq) variety of O. sativa. We assessed their phylogeny and agronomical traits, photosynthetic performance, ion contents, as well as gene expression in response to salinity stress. Salt-tolerant O. rufipogon exhibited efficient leaf photosynthesis and less damage to leaf tissues during the course of salinity treatment. In addition, O. rufipogon showed a significantly higher tissue Na + accumulation that is achieved by vacuolar sequestration compared to the salt tolerant O. sativa indica subspecies. These findings are further supported by the upregulation of genes involved with ion transport and sequestration (e.g. high affinity K + transporter 1;4 [HKT1;4], Na + /H + exchanger 1 [NHX1] and vacuolar H + -ATPase c [VHA-c]) in salt-tolerant O. rufipogon as well as by the close phylogenetic relationship of key salt-responsive genes in O. rufipogon to these in salt-tolerant wild rice species such as O. coarctata. Thus, the high accumulation of Na + in the leaves of O. rufipogon acts as a cheap osmoticum to minimize the high energy cost of osmolyte biosynthesis and excessive reactive oxygen species production. These mechanisms demonstrated that O. rufipogon has important traits that can be used for improving salinity tolerance in cultivated rice. K E Y W O R D S gene expression, ion transporters, Oryza rufipogon Griff, phylogeny, tissue Na + tolerance) is one of the most important agricultural crops and is the main source of carbohydrates for more than half of the world's population (FAO, 2019). Demand for the crop is increasing due to population growth and, to meet this demand, rice production will have to move to marginal lands many of which are salinized. Rice is susceptible to soil salinization, which is one of the major factors limiting its production (Ma et al., 2012(Ma et al., , 2018Kotula et al., 2020). Salinity stress damages leaves, reduces growth, delays panicle emergence and, most importantly, reduces yields (Caperta et al., 2020;Zeng & Shannon, 2000). A 50% yield loss is estimated at a salinity level of Celymar Angela Solis and Miing-Tiem Yong contributed equally to this study.
