In Silico Identification of Viper PhospholipaseA2 Inhibitors: Validation by in Vitro, in Vivo Studies

Overview

Journal J Mol Model

Publisher Springer

Specialty Molecular Biology

Date 2011 Mar 2

PMID 21360175

Citations 11

Authors

Amit Nargotra

Sujata Sharma

Mohd Iqbal Alam

Zabeer Ahmed

Asha Bhagat

Subhash Chander Taneja

Ghulam Nabi Qazi

Surrinder Koul

Affiliations

Soon will be listed here.

Abstract

Snake venom, particularly of vipers from the Indian subcontinent, contains Phospholipase A2 (PLA2) as one its constituents which is widely implicated in hemorrhagic, cardiac arrest and death. Development of inhibitors of the protein can facilitate the weakening or annihilation of the venom toxicity and save many human lives. In the present communication, our studies relate to the design and development of structure-based ligands as inhibitors of PLA2 of Viper venom. The study involves the computational approach towards evaluating a library of molecules comprising of natural products, and synthetic molecules through docking studies on the venom protein PDB ID: 1OXL (a dimer, available in the literature). In silico experiments have resulted in the identification of several of them as PLA2 inhibitors. The inhibitory effect of PLA2 by these compounds is attributed to a great extent to their interaction with the residues Phe 46 and Val47 of chain B of the target protein and hence these two residues are identified as the key contributor for the said activity. In order to validate the in silico findings, a selected panel of compounds have been tested by in vitro and in vivo experiments against the venom, which has led to the observance of significant corroboration between the wet lab and in silico findings, validating thereby the in silico approach used in the present study.

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