Inversion of the roles of the nucleophile and acid/base catalysts in the covalent binding of epoxyalkyl xyloside inhibitor to the catalytic glutamates of endo-1,4-beta-xylanase (XYNII): a molecular dynamics study.

X-Ray crystal structures have revealed that 2, 3-epoxypropyl-beta-D-xyloside reacts with endo-1,4-beta-xylanase (XYNII) by forming a covalent bond with Glu86. In contrast, 3, 4-epoxybutyl-beta-D-xyloside forms a covalent bond with Glu177. In the normal enzyme reaction Glu86 acts as the catalytic nucleophile and Glu177 as the acid/base catalyst. To rationalize the observed reactivity of the two mechanism-based inhibitors, we carried out eight 300 ps molecular dynamics simulations for different enzyme-inhibitor complexes. Simulations were done for both stereo isomers (R and S) of the inhibitors and for enzyme in which the protonation state of the nucleophile and acid/base catalyst was normal (Glu86 charged, Glu177 neutral) and in which the roles of the catalytic residues were reversed (Glu86 neutral, Glu177 charged). The number of reactive conformations found in each simulation was used to predict the reactivity of epoxy inhibitors. The conformation was considered to be a reactive one when at the same time (i) the proton of the catalytic acid was close (<2.9/3.4/3.9 A) to the oxirane oxygen of the inhibitor, (ii) the nucleophile was close to the terminal carbon of the oxirane group (<3.4/3.9/4.4 A) and (iii) the nucleophile approached the terminal carbon from a reactive angle (<30/45/60 degrees from an ideal attack angle). On the basis of the number of reactive conformations, 2,3-epoxypropyl-beta-D-xyloside was predicted to form a covalent bond with Glu86 and 3, 4-epoxybutyl-beta-D-xyloside with Glu177, both in agreement with the experiment. Thus, the MD simulations and the X-ray structures indicate that in the covalent binding of 3, 4-epoxybutyl-beta-D-xyloside the roles of the catalytic glutamates of XYNII are reversed from that of the normal enzyme reaction.