Phosphatases play an important role in mineralization of organic phosphorus, soil phosphorus availability and global phosphorus cycling. Release of phosphorus in different ecosystems is important for plant growth and microbial function, and may be simulated by modeling organic phosphate mineralization. The half-saturation constant (Km) and the maximum enzyme activity (Vmax) in the Michaelis-Menten equation are the two important kinetic parameters in these models, but their values have not been systematically investigated. In this study, we compiled a database of kinetic parameters of phosphatase from 139 publications, estimated the means, variations and distributions of the kinetic parameters, and tested the differences in kinetic parameters of phosphatases of different types, origins and under different incubation conditions. We also analyzed the activation energy (Ea), temperature sensitivity (Q10), optimum pH (pHopt) and sensitivity of pH (pHsen) of phosphatase activity.
Results/Conclusions
Our results indicated that: 1) Both Vmax and Km were log-normal distributed with large variations; 2) There was no significant difference in Km between the acid or alkaline phosphatases, but a significantly higher Vmax for acid phosphatases was found compared with alkaline phosphatases; 3) Km and Vmax varied with the origins of enzymes and under different incubation conditions. Plant originated enzymes had the highest Vmax while soil originated enzymes had the lowest Vmax. Larger variation in Vmax was found among the incubation times than among the incubation temperatures; 4) The mean values of Ea for acid and alkaline phosphatases were 36.30 and 23.61 KJ mol-1, respectively, with an overall mean of 34.40 KJ mol-1. The mean value of estimated pHopt for acid phosphatase was 5.2 while that for alkaline phosphatase was 9.5. The information generated in this study will be useful for phosphorus mineralization modeling and uncertainty analysis.