Structural insights into tick-borne encephalitis virus neutralization and animal protection by a therapeutic antibody

Abstract

AbstractTick-borne encephalitis virus (TBEV) causes about 5-6 thousand cases annually, while there is still no effective treatment for this virus. To fill this gap, a high-affinity chimeric anti-TBEV antibody ch14D5 has previously been constructed, and high protective activity in a murine TBEV model has been shown for this antibody. However, the mechanism of action of this antibody and the recognized epitope have not been known yet. In this study, it is shown by X-ray crystallography that this antibody recognizes a unique epitope on the lateral ridge of the D3 domain of glycoprotein E, which is readily accessible for binding. The orientation of this antibody relative to the virion surface makes bivalent binding possible, which facilitates the cross-linking of glycoprotein E molecules and thus blocking of surface rearrangements required for infection. Since the antibody tightly binds to this protein even at pH ∼ 5.0, it locks the virion in an acidic environment inside the late endosomes or phagosomes and, therefore, effectively blocks the fusion of the viral and endosomal/phagosomal membranes. We believe that this is why the ch14D5 antibody does not induce an antibody-dependent enhancement of infection in vivo, which is critical in the development of antibody-based therapeutic agents. In addition, the structure of the antibody-glycoprotein E interface can be used for the rational design of this antibody for enhancing its properties.