Water molecule-mediated selective inhibition of bacterial zinc metalloproteinases by non-hydroxamate compounds: Ab initio molecular simulations

Abstract

UDP-3-O-acyl-N acetylglucosamine deacetylase (LpxC), Zn metalloenzyme for Gram-negative bacteria is an attractive target for developing novel therapeutic agents. Since LpxC has the similar binding pocket as the human matrix metalloproteinases (MMPs), LpxC inhibitors might also inhibit MMP functions producing side effects in human bodies. Here, we investigated specific interactions between LpxC/MMP and their inhibitors using ab initio molecular simulations to elucidate the reason of selective inhibition for LpxC by non-hydroxamate compounds. The evaluated binding properties between LpxC and the compounds are comparable to the trend of their observed inhibitory affinities. It was also elucidated that compound 22 binds most strongly to LpxC due to its specific interactions with Zn ion and Asp241 side chain of LpxC. In contrast, the interactions between the compounds and MMP are significantly weakened due to the water molecules, which are tightly coordinated with the Zn ion in MMP and interrupt the binding of the compounds to the Zn ion. Accordingly, the present molecular simulations revealed that these water molecules around the Zn ion in MMP are causally related to the selective inhibition of these compounds for LpxC rather than MMP.