Coastal plants often experience salinity and waterlogging simultaneously, yet their combined effects are rarely tested. In a 35-day greenhouse experiment on Jeju Island, we exposed Hibiscus hamabo , Paliurus ramosissimus , Litsea japonica , and Vitex rotundifolia to salinity, waterlogging, and salinity–waterlogging. We quantified growth, deterioration (mortality, survival time, defoliation, visible damage), leaf gas exchange (net CO₂ assimilation, Aₙ; intrinsic water-use efficiency), and Na⁺ and K⁺ contents. Due to the small size of individuals, Paliurus ramosissimus did not yield sufficient material and was excluded from gas-exchange and ion analyses. Salinity–waterlogging caused the strongest deterioration in all species and generally elevated Na⁺/K⁺ ratios relative to single stress. H. hamabo initiated decline earliest but sustained lower mortality and longer survival, maintained Aₙ near pre-treatment despite reduced stomatal conductance, and retained K⁺, particularly in roots. By contrast, L. japonica and V. rotundifolia showed near-cessation of photosynthesis under salinity; L. japonica exhibited root-centric dysfunction under waterlogging with concurrent declines in root Na⁺ and K⁺. We infer that tolerance in H. hamabo reflects coordinated ion homeostasis (notably K⁺ retention) and stomatal–nonstomatal adjustments that stabilize Aₙ, likely aided by an abscission-mediated “salt storage and disposal” strategy. Co-occurring shrubs display partial or organ-specific responses insufficient to withstand the combined stress. These results identify H. hamabo as a plausible semi-mangrove candidate for future range expansion and coastal planting under warming climates and highlight the need to consider differential sensitivities to hypoxia and ionic toxicity in species selection.
Park et al. (Fri,) studied this question.
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