Unravelling the plausible metal-dependent catalytic mechanism of Inositol monophosphatase ortholog from Pseudomonas aeruginosa through the lenses of macromolecular crystallography and enzyme kinetics

The inositol monophosphatase (IMPase) orthologue is pivotal for virulence, pathogenesis, and biofilm regulation, and is therefore considered a potential drug target in Pseudomonas aeruginosa and other bacterial pathogens. The mammalian IMPase orthologue is an established drug target for bipolar disorder. The precise catalytic mechanism in this class of enzymes remains obscure despite five to six decades of extensive efforts and detailed studies of substrate, transition-state analogue, and product-bound structures. Here, we have solved the crystal structures of the IMPase orthologue from Pseudomonas aeruginosa (PaIMPase), capturing pre- and post-catalytic snapshots of metal-substrate- and metal-product-mimic-bound states. Moreover, we solved the metal-substrate transition-state-analogue-bound crystal structure of the enzyme. Critical evaluation of these high-resolution crystal structures of PaIMPase complexed with substrate, transition-state analogue, and product mimic (myo-inositol and phosphate) supports three Mg2+-dependent catalytic mechanisms of PaIMPase. The structural snapshots indicate that, at the enzyme active site, a metal (Mg2+)-coordinating water molecule, activated by two bound Mg2+ ions and the active-site-proximal Threonine/Aspartate dyad, attacks the central phosphorus atom of the bound substrate, leading to formation of a trigonal bipyramidal transition state. Following that, the immediate breakdown of the P-O bond results in the formation of inositolate and phosphate ions. The second water molecule, activated by another Mg2+ dyad, facilitates the departure of myo-inositol and phosphate from the active site. The detailed mechanistic insights gained from this work may offer a foundation for the rational design of precise inhibitors against PaIMPase.