Yan_2019_Molecules_24_

Reference

Title : Catalytic Hydrolysis Mechanism of Cocaine by Human Carboxylesterase 1: An Orthoester Intermediate Slows Down the Reaction - Yan_2019_Molecules_24_
Author(s) : Yan M , Zhang Z , Liu Z , Zhang C , Zhang J , Fan S , Yang Z
Ref : Molecules , 24 : , 2019
Abstract :

Human carboxylesterase 1 (hCES1) is a major carboxylesterase in the human body and plays important roles in the metabolism of a wide variety of substances, including lipids and drugs, and therefore is attracting more and more attention from areas including lipid metabolism, pharmacokinetics, drug-drug interactions, and prodrug activation. In this work, we studied the catalytic hydrolysis mechanism of hCES1 by the quantum mechanics computation method, using cocaine as a model substrate. Our results support the four-step theory of the esterase catalytic hydrolysis mechanism, in which both the acylation stage and the deacylation stage include two transition states and a tetrahedral intermediate. The roles and cooperation of the catalytic triad, S221, H468, and E354, were also analyzed in this study. Moreover, orthoester intermediates were found in hCES1-catalyzed cocaine hydrolysis reaction, which significantly elevate the free energy barrier and slow down the reaction. Based on this finding, we propose that hCES1 substrates with beta-aminocarboxylester structure might form orthoester intermediates in hCES1-catalyzed hydrolysis, and therefore prolong their in vivo half-life. Thus, this study helps to clarify the catalytic mechanism of hCES1 and elucidates important details of its catalytic process, and furthermore, provides important insights into the metabolism of hCES1 substrates and drug designing.

PubMedSearch : Yan_2019_Molecules_24_
PubMedID: 31717501
Gene_locus related to this paper: human-CES1

Related information

Substrate Cocaine
Gene_locus human-CES1

Citations formats

Yan M, Zhang Z, Liu Z, Zhang C, Zhang J, Fan S, Yang Z (2019)
Catalytic Hydrolysis Mechanism of Cocaine by Human Carboxylesterase 1: An Orthoester Intermediate Slows Down the Reaction
Molecules 24 :

Yan M, Zhang Z, Liu Z, Zhang C, Zhang J, Fan S, Yang Z (2019)
Molecules 24 :