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Target # 23: Ebola GP1

Tag: boinc:sidock@home
Published 2024-07-11 11:02:55


Dear participants,

as target # 22 is almost finished, we are glad to introduce the next target. Most of you have voted for Ebolavirus glycoprotein (GP) (174 out of 425 votes, wow!)

The Ebola virus is a highly virulent pathogen responsible for causing Ebola hemorrhagic fever, a severe and often fatal disease. A key factor in the virus's ability to infect host cells and cause disease is its surface glycoprotein (GP), making it an attractive target for antiviral drug development. The Ebola GP is a trimeric protein composed of two subunits per monomer: GP1, responsible for receptor binding, and GP2, which mediates fusion between the viral and host cell membranes. Initially synthesized as a precursor protein, the GP is cleaved by host proteases (furin, cathepsin) into its functional subunits, a process essential for its role in mediating viral entry. The GP facilitates the virus's attachment to the host cell surface, followed by conformational changes that enable membrane fusion, allowing the virus to enter the host cell (to the host endosomal Niemann-Pick C1 (NPC1) receptor or via direct membrane binding; Vaknin et al.; ACS Infect. Dis. 2024, 10, 5, 1590–1601).

Targeting the GP for drug development is advantageous due to its essential role in viral infection, its highly conserved structure among different Ebola virus strains, and the availability of specific binding cavities that can accommodate small-molecule inhibitors. Structural studies using techniques such as X-ray crystallography have identified these binding cavities and elucidated the GP's conformation in both its free and inhibited states. These insights enable the design of drugs that can specifically bind to and inhibit the GP by stabilizing it in its pre-fusion conformation or interfering with its cleavage, thereby preventing the necessary conformational changes for membrane fusion. We will employ high-resolution structures to conduct virtual screening experiments coupled to molecular dynamics simulations to ultimately identify potential GP inhibitors/modulators.

Promising compounds identified through these computational methods will hopefully undergo further validation using biochemical assays, pseudovirus entry assays, and structural analyses to confirm their inhibitory activity. Targeting the GP offers specificity, as it minimizes off-target effects on host cells and reduces the likelihood of resistance development. Moreover, due to the conserved nature of the GP, drugs targeting it could be effective against multiple Ebola virus strains and variants.

We hope that our computations will contribute to the fight against Ebola!


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