A bioinformatic approach to establish P38? MAPK inhibitory mechanism of selected natural products in psoriasis-Supplementary data
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Date
2022-02
Journal Title
Journal ISSN
Volume Title
Publisher
CSIR-NIScPR
Abstract
In the present study, molecular docking studies of some selected natural products were carried out to identify the potential inhibitors and subsequently to suggest their mechanism of action in relation to P38? mitogen-activated protein kinases (P38? MAPK) enzyme. Psoriasis is an inflammatory disorder characterized by skin hyper-proliferation, differentiation in keratin expression, and increased production of pro-inflammatory cytokines. Increased expression of phosphorylated P38? MAPK in the cytoplasm and nucleus is observed in psoriatic lesions. Twelve natural antipsoriatic agents were included in the study and their molecular docking studies were carried out using AutoDock 4.2 simulator using a Lamarckian genetic algorithm. The crystal structure of P38? MAPK was retrieved from the protein data bank and three-dimensional chemical structures of natural ligands were prepared using ChemSketch 2015. Results indicated that all the natural ligands were fitted into the active site. Hypericin and Catechin (?9.00 and ?8.05 kcal/mol, respectively) have shown good binding efficacy among other ligands. However, only Epicatechin interacted with residues in the enzyme required for enzyme inhibition. The study concludes that the Epicatechin effectively inhibited the enzyme and proved itself to be a type-I1/2 inhibitor of the enzyme among other natural ligands and responsible for the treatment of psoriasis preclinically through this mechanism of action.
Description
Keywords
Autoimmune disease, Docking study, Mitogen-activated protein kinase, Molecular interactions, Skin disorder
Citation
Agrawal Anurag, Awasthi Rajendra, T Kulkarni Giriraj, Lakshmayya. A bioinformatic approach to establish P38? MAPK inhibitory mechanism of selected natural products in psoriasis-Supplementary data. Indian Journal of Biochemistry & Biophysics. 2022 Feb; 59(2): 165-171