Diurnal Regulation of SOS Pathway and Sodium Excretion Underlying Salinity Tolerance of Vigna marina.

Vigna marina (Barm.) Merr. is adapted to tropical marine beaches and has an outstanding tolerance to salt stress. Given there are growing demands for cultivating crops in saline soil or with saline water, it is important to understand how halophytic species are adapted to the saline environments. Here we revealed by positron-emitting tracer imaging system (PETIS) that V. marina actively excretes sodium from the root during the light period but not the dark period. The following whole genome sequencing accompanied with forward genetic study identified a QTL region harbouring SOS1, encoding plasma membrane Na/H antiporter, which was associated with not only salt tolerance but also the ability of sodium excretion. We also found the QTL region contained a large structural rearrangement that suppressed recombination across ~14 Mbp, fixing multiple gene loci potentially involved in salt tolerance. RNA-seq and promoter analyses revealed SOS1 in V. marina was highly expressed even without salt stress and its promoter shared common cis-regulatory motifs with those exhibiting similar expression profiles. Interestingly, the cis-regulatory motifs seemed installed by a transposable element (TE) insertion. Though not identified by genetic analysis, the transcriptome data also revealed SOS2 transcription was under diurnal regulation, explaining the pattern of sodium excretion together with upregulated expression of SOS1. Altogether, the study elucidated one aspect of the strategy adopted by V. marina to adapt to marine beach, which is highly saline and transpiring.