Novel Insights into Understanding the Molecular Dialogues Between Bipolaroxin and the Gα and Gβ Subunits of the Wheat Heterotrimeric G-Protein During Host-Pathogen Interaction

Overview

Journal Antioxidants (Basel)

Date 2022 Sep 23

PMID 36139828

Authors

Deepti Malviya

Udai B Singh

Budheswar Dehury

Prakash Singh

Manoj Kumar

Shailendra Singh

Anurag Chaurasia

Manoj Kumar Yadav

Raja Shankar

Manish Roy

Jai P Rai

Arup K Mukherjee

Ishwar Singh Solanki

Arun Kumar

Sunil Kumar

Harsh V Singh

Affiliations

Soon will be listed here.

Abstract

Spot blotch disease of wheat, caused by the fungus (Sacc.) Shoem., produces several toxins which interact with the plants and thereby increase the blightening of the wheat leaves, and Bipolaroxin is one of them. There is an urgent need to decipher the molecular interaction between wheat and the toxin Bipolaroxin for in-depth understanding of host-pathogen interactions. In the present study, we have developed the three-dimensional structure of G-protein alpha subunit from . Molecular docking studies were performed using the active site of the modeled G-protein alpha and cryo-EM structure of beta subunit from and 'Bipolaroxin'. The study of protein-ligand interactions revealed that six H-bonds are mainly formed by Glu29, Ser30, Lys32, and Ala177 of G-alpha with Bipolaroxin. In the beta subunit, the residues of the core beta strand domain participate in the ligand interaction where Lys256, Phe306, and Leu352 formed seven H-bonds with the ligand Bipolaroxin. All-atoms molecular dynamics (MD) simulation studies were conducted for G-alpha and -beta subunit and Bipolaroxin complexes to explore the stability, conformational flexibility, and dynamic behavior of the complex system. studies clearly indicated that application of Bipolaroxin significantly impacted the physio-biochemical pathways in wheat and led to the blightening of leaves in susceptible cultivars as compared to resistant ones. Further, it interacted with the Gα and Gβ subunits of G-protein, phenylpropanoid, and MAPK pathways, which is clearly supported by the qPCR results. This study gives deeper insights into understanding the molecular dialogues between Bipolaroxin and the Gα and Gβ subunits of the wheat heterotrimeric G-protein during host-pathogen interaction.

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