The role of sulfate as a competitive inhibitor of enzymatically-mediated heavy metal uptake by Citrobacter sp: implications in the bioremediation of acid mine drainage water using biogenic phosphate precipitant

Heavy metals can be removed from solution via biocrystallization with enzymaticallyliberated inorganic phosphate, according to Michaelis±Menten kinetics, in free whole cells and cells immobilized within polyacrylamide gel in a ¯ow-through reactor. Sulfate is a competitive inhibitor of phosphate release and a predictive model was developed and shown to describe the effect of sulfate on the ef®ciency of phosphate release by ¯ow-through columns. The inhibitory effect was substantially less than anticipated in the case of metal removal by the columns. In the case of lanthanum removal metal removal ef®ciency was restored by increasing the substrate concentration in accordance with model predictions. In the case of uranyl ion its removal with an equivalent substrate supplement increased the activity by 20% over the initial value at a limiting ¯ow rate. Since the initial loss in activity in the presence of 40 mmol dm À3 SO 4 2À (approximately twice the K i value) was only approximately 20% with both metals this was considered to be a minor problem for bioprocess application. In con®rmation, calculations made from a published `case history' of application of the system to the bioremediation of acid mine drainage water (AMD) containing 0.22 mmol dm À3 of uranyl ion and 35 mmol dm À3 of SO 4 2À showed that the benchscale model is a good representation of performance under actual load conditions.