Constant PH Molecular Dynamics (CpHMD) and Molecular Docking Studies of CquiOBP1 PH-induced Ligand Releasing Mechanism

Overview

Journal J Mol Model

Publisher Springer

Specialty Molecular Biology

Date 2012 Nov 27

PMID 23179772

Citations 7

Authors

Wen-Ting Chu

Ji-Long Zhang

Qing-Chuan Zheng

Lin Chen

Yun-Jian Wu

Qiao Xue

Hong-Xing Zhang

Affiliations

Soon will be listed here.

Abstract

The odorant binding protein of Culex quinquefasciatus (CquiOBP1), expressed on the insect antenna, is crucial for the investigation of trapping baited with oviposition semi-chemicals and controlling mosquito populations. The acidic titratable residues pKa prediction and the ligand binding poses investigation in two systems (pH 7 and pH 5) are studied by constant pH molecular dynamics (CpHMD) and molecular docking methods. Research results reveal that the change of the protonation states would disrupt some important H-bonds, such as Asp 66-Asp 70, Glu 105-Asn 102, etc. The cleavage of these H-bonds leads to the movement of the relative position of hydrophobic tunnel, N- and C- termini loops and pH-sensing triad (His23-Tyr54-Val125) in acid solution. Ligand MOP has lower affinity and shows different binding poses to protein CquiOBP1 at pH 5. This ligand may be released from another tunnel between helices α3 and α4 in acidic environment. However, it would bind to the protein with high affinity in neutral environment. This work could provide more penetrating understanding of the pH-induced ligand-releasing mechanism.

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