Computer, Simulated Evaluation of Possible Mechanisms for Sequestering Metal Ion Activity in Plant Vacuoles

Abstract

Various mechanisms have been suggested for sequestering Zn ion activity in vacuoles of Zn-tolerant plants. One of these mechanisms, complexation in the vacuole with organic acids, has received some support in the recent literature. However, the lack of experimental evidence for anticipated vacuolar compartmentation and concerning the nature of metal-ligand species occurring in the vacuole has been criticized. In this study we have used computer modeling of chemical equilibria to predict the metalligand species in vacuoles of tobacco (Nicotiana tabacum) cultured cells. Results of this thermodynamic evaluation support the conclusion that citrate in the concentration range encountered in tobacco cultured cells exposed to 300 or 2000 mum Zn has high potential for forming soluble complexes with Zn, over the entire probable range of vacuolar pH 4 to 7. Complexation of Zn with oxalate is also predicted, especially in cells exposed to high Zn levels. Malate, though the most abundant acid present, showed little potential for competing with other ligands for Zn. Overall, results suggest that vacuolar sequestration of Zn by high levels of vacuolar citrate may be a central mechanism in the accumulation of Zn in plants exposed to either low or high levels of this metal.