Subcellular distribution of molybdenum, ultrastructural and antioxidative responses in soybean seedlings under excess molybdenum stress.

Some studies have shown that excess molybdenum (Mo) could produce toxic effects on plants. However, little is known about the subcellular distribution of Mo and cell ultrastructure within plants under excess Mo stress. Here, we comprehensively analyzed the changes of Mo distribution in subcellular fractions, cell ultrastructure and antioxidant enzymes in leaves and roots of soybean seedlings in response to excess Mo stress. The results showed that roots exhibited higher Mo accumulation than leaves at the 100 mg L-1 Mo level, about 38.58-, 171.48- and 52.99-fold higher in cell walls, cell organelles and soluble fractions, respectively. Subcellular fractionations of Mo-containing tissues indicated that approximately 90% of Mo was accumulated in the soluble fractions and cell walls of the roots and leaves, and soluble fractions (accumulated 66.3-72.2% Mo) might serve as an effective storage site for excess Mo. Furthermore, excess Mo caused ultrastructural alterations in roots and leaves of soybean seedlings, leading to structural abnormality of chloroplast in leaf cells, plasmolysis, cellular deformity, vacuole enlargement and the swelling of cell wall and cytoplasm in root cells. Meanwhile, under excess Mo stress, the activity of POD, CAT and APX enzymes in roots was 1.43, 2.35 and 1.23 times that under standard Mo condition, while that of SOD and CAT enzymes in leaves was 1.23 and 1.94 times, respectively. This study provided novel insights into the mechanisms of excess Mo toxicity in soybean seedlings.