Abstract
Background: Rift Valley fever virus (RVFV) is an emerging arbovirus infecting both animals and humans. Any form of direct contact with body fluids, blood or tissue of infected animals is the mode of transmission of this pathogen. Despite being an emerging virus, no proper vaccinations are yet available for the public. Our objective is to compose a multiepitope vaccine utilizing immuno-bioinformatics as a strategy against RVFV. Methods: To identify immunodominant epitopes and design a potent vaccine candidate, we applied a series of immunoinformatic approaches with molecular dynamics and immune response simulation frameworks. Results: A glycoprotein with the highest antigenicity was selected and employed for determining promising epitopes. We selected T cell epitopes based on their immunological potencies and cytokine inducing properties, while B cell epitopes were selected based on their antigenic features. Finally, we selected four cytotoxic T-lymphocyte, two helper T-lymphocyte, and three linear B-lymphocyte epitopes that were arranged into a vaccine construct with appropriate adjuvants and linkers. The chimera protein was modeled, refined, and validated prior to docking against toll-like receptor 4. Docking studies suggest strong binding interactions while dynamics simulation revealed the stable nature of the docked complex. Furthermore, the immune simulation showed robust and prolonged immune responses with rapid antigen clearance. Finally, codon optimization and cloning conducted with Escherichia coli K12 suggests high translation efficiency within the host system. Conclusion: We believe that our designed multiepitope vaccine is a promising prophylactic candidate against RVFV pathogenesis.
Highlights
Rift Valley fever virus (RVFV) is a risk to worldwide public health and farming, especially in parts of Africa, Madagascar, and the Middle East[1]
RVFV proteome and selected antigen Amino acid sequences of a total of 232 RVFV proteins were collected from the ViPR database
Potential cytotoxic T-lymphocyte (CTL), helper T-lymphocyte (HTL) and linear B-lymphocyte (LBL) epitopes NetCTL v1.2 server predicted 135 unique 9-mer CTL epitopes in total
Summary
Rift Valley fever virus (RVFV) is a risk to worldwide public health and farming, especially in parts of Africa, Madagascar, and the Middle East[1]. Epidemic alarms have persuaded several national and international health organizations to issue cautions about the rising risk of infection in Rift Valley fever (RVF) uninfected countries, like Europe and USA, due to the existence of vectors of transmission which are highly permissive, further compounded by global animal trade[7,8,9]. These reports unanimously concluded that coordinated efforts are needed in order to prepare for preventive measures against the recurrent emergence of RVFV. The immune simulation showed robust and prolonged immune responses with
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