The effects of CO enrichment on water balance and nitrogen (N) assimilation in cucumber (Cucumis sativus L. cv. Jinyou No.35) seedlings under salt stress were investigated. Two-way randomized block design was used: the main treatment consisted of two [CO] levels, ambient and enriched (400 and 800 ± 40 μmol mol, respectively), and the minor treatment consisted on two salinity treatment levels, 0 and 80 mmol L NaCl. The results showed that, under the experimental conditions, enriched [CO] and salt stress significantly inhibited the N assimilation process in cucumber leaves; however, enriched [CO] had no effect on the nitrate (NO) reduction or ammonium (NH) assimilation of leaves under salt stress, inhibiting only the transamination. Moreover, enriched [CO] increased the plasma membrane H-ATPase activity, vacuolar membrane H-ATPase activity and root hydraulic conductivity under salt stress, thereby increasing the ion selective absorption and water absorption capacity. To a certain extent, enriched [CO] promoted the accumulation of K in plants, which significantly reduced the Na/K ratio; moreover, the enrichment ultimately improved the water state conditions and helped to maintain the ion balance in plants under stress, ensuring normal enzymatic activity.
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