Cell-specific Na+ accumulation is linked to symplastic transport in tomato leaves

Soil salinization is a growing global threat that limits crop productivity. To cope with sodium (Na) stress, plants have evolved tolerance mechanisms, including excluding Na from shoot tissues and tolerating elevated Na within shoots through tissue- and cellular-level mechanisms. Most current knowledge of Na accumulation comes from organ- or whole-plant measurements that lack the spatial resolution needed to resolve cellular tolerance mechanisms. Here, we used histological approaches to map leaf Na distribution in tomato (Solanum) species with contrasting salt-tolerance strategies. In the Na-excluding domesticated tomato (cv. M82), Na was largely confined to the bundle sheath, whereas Na-including wild relatives accumulated Na throughout the blade mesophyll. Consistent with these cell population-specific Na patterns, M82, but not S. pennellii, exhibited reduced symplastic transport and plasmodesmal permeability under salt stress. A genetic screen combined with transcriptome profiling implicated Plasmodesmata-Located Protein 1 (PDLP1), a regulator of callose-mediated plasmodesmal closure, in establishing symplastic domains in M82 that restrict Na movement into the mesophyll. Moreover, PDLP1 expression negatively correlated with mesophyll Na+ levels across wild and domesticated tomatoes. Collectively, these results link cellular Na enrichment patterns to symplastic connectivity and suggest that PDLP1-mediated regulation of plasmodesmata contributes to leaf-level salt-tolerance strategies. HighlightsO_LICell type-specific Na accumulation differs between domesticated tomato (Solanum lycopersicum cv. M82) and its wild relative S. pennellii. C_LIO_LIAdditional salt-tolerant wild tomato relatives exhibit leaf Na enrichment patterns similar to S. pennellii. C_LIO_LISalt stress reduces symplastic transport and plasmodesmal permeability in M82 leaves but not in S. pennellii. C_LIO_LIAn introgression line (IL6-4) between the two tomato species, which carries S. pennellii Plasmodesmata-Located Protein 1 (SpPDLP1), shows S. pennellii-like Na enrichment patterns. C_LIO_LIPDLP1 expression shows a negative correlation with mesophyll Na+ levels across tomato species. C_LI