Antiviral Activity, Pharmacoinformatics, Molecular Docking, and Dynamics Studies of Against Nipah Virus by Targeting Envelope Glycoprotein: Emerging Strategies for Developing Antiviral Treatment

Overview

Journal Bioinform Biol Insights

Publisher Sage Publications

Specialty Biology

Date 2024 Jul 29

PMID 39072258

Authors

Otun Saha

Noimul Hasan Siddiquee

Rahima Akter

Nikkon Sarker

Uditi Paul Bristi

Khandokar Fahmida Sultana

Sm Lutfor Rahman Remon

Afroza Sultana

Tushar Ahmed Shishir

Md Mizanur Rahaman

Firoz Ahmed

Foysal Hossen

Mohammad Ruhul Amin

Mir Salma Akter

Affiliations

Soon will be listed here.

Abstract

The Nipah virus (NiV) belongs to the genus is a serious public health concern causing numerous outbreaks with higher fatality rate. Unfortunately, there is no effective medication available for NiV. To investigate possible inhibitors of NiV infection, we used in silico techniques to discover treatment candidates in this work. As there are not any approved treatments for NiV infection, the NiV-enveloped attachment glycoprotein was set as target for our study, which is responsible for binding to and entering host cells. Our in silico drug design approach included molecular docking, post-docking molecular mechanism generalised born surface area (MM-GBSA), absorption, distribution, metabolism, excretion/toxicity (ADME/T), and molecular dynamics (MD) simulations. We retrieved 418 phytochemicals associated with the neem plant () from the IMPPAT database, and molecular docking was used to ascertain the compounds' binding strength. The top 3 phytochemicals with binding affinities of -7.118, -7.074, and -6.894 kcal/mol for CIDs 5280343, 9064, and 5280863, respectively, were selected for additional study based on molecular docking. The post-docking MM-GBSA of those 3 compounds was -47.56, -47.3, and -43.15 kcal/mol, respectively. As evidence of their efficacy and safety, all the chosen drugs had favorable toxicological and pharmacokinetic (Pk) qualities. We also performed MD simulations to confirm the stability of the ligand-protein complex structures and determine whether the selected compounds are stable at the protein binding site. All 3 phytochemicals, Quercetin (CID: 5280343), Cianidanol (CID: 9064), and Kaempferol (CID: 5280863), appeared to have outstanding binding stability to the target protein than control ribavirin, according to the molecular docking, MM-GBSA, and MD simulation outcomes. Overall, this work offers a viable approach to developing novel medications for treating NiV infection.

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