Abstract
Hepatitis C virus (HCV) is a species-specific pathogenic virus that infects only humans and chimpanzees. Previous studies have indicated that interactions between the HCV E2 protein and CD81 on host cells are required for HCV infection. To determine the crucial factors for species-specific interactions at the molecular level, this study employed in silico molecular docking involving molecular dynamic simulations of the binding of HCV E2 onto human and rat CD81s. In vitro experiments including surface plasmon resonance measurements and cellular binding assays were applied for simple validations of the in silico results. The in silico studies identified two binding regions on the HCV E2 loop domain, namely E2-site1 and E2-site2, as being crucial for the interactions with CD81s, with the E2-site2 as the determinant factor for human-specific binding. Free energy calculations indicated that the E2/CD81 binding process might follow a two-step model involving (i) the electrostatic interaction-driven initial binding of human-specific E2-site2, followed by (ii) changes in the E2 orientation to facilitate the hydrophobic and van der Waals interaction-driven binding of E2-site1. The sequence of the human-specific, stronger-binding E2-site2 could serve as a candidate template for the future development of HCV-inhibiting peptide drugs.
Highlights
Hepatitis C virus (HCV) affects approximately 170 million people worldwide [1] and is one of the major causes of liver diseases, including chronic hepatitis, liver cirrhosis, and hepatocellular carcinoma [2]
The major difference between the two structures is located at the flexible loop from residues 173 to 186, meaning that this region may be the cause of HCV envelope glycoprotein 2 (E2) binding only to human CD81, but not to rat CD81 (Fig 2A)
HCV binds to human cells with high specificity through the interactions between its E2 protein and host cell receptor CD81 [17,52], and humans and chimpanzees are the only known species that can be infected by HCV [32,33]
Summary
Hepatitis C virus (HCV) affects approximately 170 million people worldwide [1] and is one of the major causes of liver diseases, including chronic hepatitis, liver cirrhosis, and hepatocellular carcinoma [2]. The current standard treatments for HCV infection are combinations of pegylated IFN-α, ribavirin, RNA-dependent RNA polymerase, and NS3-NS4-NS5 protease inhibitors, which generally result in 67%–75% sustained viral response rates [3,4,5,6]. These treatments can induce various side effects, and the resistance of HCV to these treatments has been discovered [7,8,9]. There is a need for alternative strategies to treat HCV infections.
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