Quantum mechanical study of Burkholderia cepacia lipase enantioselectivity

Quantum mechanical, semiempirical (AM1) and ab initio (6-31G*) study of the Burkholderia cepacia lipase (BCL) catalysed reactions of the secondary alcohol esterification and its ester hydrolysis is presented. We have selected BCL for our study because of numerous experimental results available, but also because of its broad selectivity and stability that makes it interesting for industrial use. Previously we developed models for predicting lipase stereo-selectivity towards primary and secondary alcohols according to their structural parameters. In this work we show that not all of the experimentally determined binding modes are catalytically competent and that additional molecular modelling should be accomplished in order to find good starting points to study chemical reactions. The binding modes from which chemical modification of a substrate is possible are the most relevant for understanding enzyme selectivity and for the rational enzyme engineering. o investigated the influence of the tetrahedral atom type, C and P, upon the energy barriers in the proton transfer reactions from the catalytic histidine (His286) to either the catalytic serine (Ser87) or the alcohol oxygen of the substrate.