Interactive effects of NaCl salinity and elevated atmospheric CO2 concentration on growth, photosynthesis, water relations and chemical composition of the potential cash crop halophyte Aster tripolium L.

This study was aimed at obtaining detailed information about the interaction of NaCl-salinity and elevated atmospheric CO2 concentration in the potential cash crop halophyte Aster tripolium. Plants were irrigated with 5 different salinity levels (0, 25, 50, 75 and 100% sws) under ambient and elevated (520 ppm) CO2. Under saline conditions leaf water potential decreased to a value below the one of the nutrient solution. Osmotic adjustment was mainly due to the accumulation of sodium and chloride (includer type). However, the salt was unequally distributed within the plants. K/Na selectivity was high in the lateral roots and low in the petioles, so that these organs served as “salt filters” which prevented an excessive salt accumulation and ion toxicity in the leaf blades and in the main root, the storage organ for organic substances. Despite some signs of ion toxicity and nutrial imbalance, these factors do not seem to be predominantly responsible for the limited salinity tolerance of A. tripolium. In order to maintain a positive water balance the salt treated plants increased stomatal resistance. But at the same time stomata closure led to a significant decrease in photosynthesis and thus in WUE. The impaired assimilation rate contributed to the significant growth depression (50% reduction of the maximum yield between 50% and 75% sws), together with the higher energy consumption needed for various salinity tolerance mechanisms, e.g. for an enhanced synthesis of compatible solutes (proline, carbohydrates) and stress-induced proteins. Elevated atmospheric CO2 concentration led to a significant increase in photosynthesis and in WUE. The latter indicates, together with a higher water potential, that the water relations of the plants had improved. By reducing stomatal resistance energy gain was maximized. The additional supply with energy-rich organic substances was not employed for producing more biomass but for increasing the investment in salinity tolerance mechanisms, e.g. for an enhanced synthesis of proline, carbohydrates and proteins. These mechanisms led to a higher survival rate under saline conditions, i.e. to an improved salt tolerance. The results of the study indicate that A. tripolium is a promising cash crop halophyte which will probably benefit from rising atmospheric CO2 concentrations in future.