In this study, we aimed to evaluate the immunogenic profile of a chimeric DNA-based hepatitis C virus (HCV) vaccine candidate encoding the full-length viral core-E1-E2 (HCV-CE) fragment. The vaccine candidate was designed to uniformly express the HCV genotype 4 core-E1-E2 protein. The recombinant HCV-CE protein was bacterially expressed in C41 (DE3) cells, and then BALB/c mice were immunized with different combinations of DNA/DNA or DNA/protein prime/boost immunizations. The proper construction of our vaccine candidate was confirmed by specific amplification of the encoded fragments and basic local alignment search tool (BLAST) results of the nucleotide sequence, which revealed a high degree of similarity with several HCV serotypes/genotypes. The platform for bacterial expression was optimized to maximize the yield of the purified recombinant HCV-CE protein. The recombinant protein showed high specific antigenicity against the sera of HCV-infected patients according to the ELISA and western blot results. The predicted B- and T-cell epitopes showed high antigenic and interferon-γ (IFN-γ) induction potential, in addition to cross-genotype conservation and population coverage. The mice antisera further demonstrated a remarkable ability to capture 100% of the native viral antigens circulating in the sera of HCV patients, with no cross-reactivity detected in control sera. In conclusion, the proposed HCV vaccination strategy demonstrated promising potential regarding its safety, immunogenicity, and population coverage.
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