Diverse Phosphoserine Phosphatases Exhibit Maximum Activity at an Intermediate Binding Affinity in Accord with the Sabatier Principle of Catalysis

Abstract

A unified framework to rationalize enzymatic activity is essential to understand cellular function and metabolic evolution. Recent studies have shown that the activity of several hydrolases is maximized when the substrate binding affinity (Michaelis-Menten constant:) is neither too strong nor too weak. This is because an intermediate resolves the trade-off between, in accord with the Sabatier principle of artificial catalysis. However, it remains unclear whether this concept is applicable to enzymes in general, especially for those which catalyze the same reaction but have evolved under different selection pressures due to the phylogeny or physiology of the host organism. Here, we demonstrate that the activity of 10 distinct wild-type phosphoserine phosphatases (PSP) exhibits a maximum at an intermediate binding affinity , indicating that they also follow the Sabatier principle. Furthermore, by considering not only but also the equilibrium rate constant of each enzyme, we have succeeded in rationalizing the PSP activity quantitatively.