Computational Exploration of Potential Pharmacological Inhibitors Targeting the Envelope Protein of the Kyasanur Forest Disease Virus.
Sharanappa AchappaNayef Abdulaziz AldabaanShivalingsarj V DesaiUday M MuddapurIbrahim Ahmed ShaikhMater H MahnashiAbdullateef A AlshehriBasheerahmed Abdulaziz MannasahebAejaz Abdullatif KhanPublished in: Pharmaceuticals (Basel, Switzerland) (2024)
The limitations of the current vaccination strategy for the Kyasanur Forest Disease virus (KFDV) underscore the critical need for effective antiviral treatments, highlighting the crucial importance of exploring novel therapeutic approaches through in silico drug design. Kyasanur Forest Disease, caused by KFDV, is a tick-borne disease with a mortality of 3-5% and an annual incidence of 400 to 500 cases. In the early stage of infection, the envelope protein plays a crucial role by facilitating host-virus interactions. The objective of this research is to develop effective antivirals targeting the envelope protein to disrupt the virus-host interaction. In line with this, the 3D structure of the envelope protein was modeled and refined through molecular modeling techniques, and subsequently, ligands were designed via de novo design and pharmacophore screening, yielding 12 potential hits followed by ADMET analysis. The top five candidates underwent geometry optimization and molecular docking. Notably, compounds L4 (SA28) and L3 (CNP0247967) are predicted to have significant binding affinities of -8.91 and -7.58 kcal/mol, respectively, toward the envelope protein, based on computational models. Both compounds demonstrated stability during 200 ns molecular dynamics simulations, and the MM-GBSA binding free-energy values were -85.26 ± 4.63 kcal/mol and -66.60 ± 2.92 kcal/mol for the envelope protein L3 and L4 complexes, respectively. Based on the computational prediction, it is suggested that both compounds have potential as drug candidates for controlling host-virus interactions by targeting the envelope protein. Further validation through in-vitro assays would complement the findings of the present in silico investigations.
Keyphrases
- molecular docking
- molecular dynamics simulations
- disease virus
- protein protein
- early stage
- binding protein
- risk factors
- emergency department
- cardiovascular disease
- squamous cell carcinoma
- cancer therapy
- small molecule
- drug delivery
- high throughput
- coronary artery disease
- human health
- dengue virus
- single cell
- lymph node