Structural and functional characterization of an anti-West Nile virus monoclonal antibody and its single-chain variant produced in glycoengineered plants

摘要

Previously, our group engineered a plant-derived monoclonal antibody (MAb pE16) that efficiently treated West Nile virus (WNV) infection in mice. In this study, we developed a pE16 variant consisting of a single-chain variable fragment (scFv) fused to the heavy chain constant domains (CH) of human IgG (pE16scFv-CH). pE16 and pE16scFv-CH were expressed and assembled efficiently in Nicotiana benthamiana ΔXF plants, a glycosylation mutant lacking plant specific N-glycan residues. Glycan analysis revealed that ΔXF plant-derived pE16scFv-CH (ΔXFpE16scFv-CH) and pE16 (ΔXFpE16) both displayed a mammalian glycosylation profile. ΔXFpE16 and ΔXFpE16scFv-CH demonstrated equivalent antigen binding affinity and kinetics, and slightly enhanced neutralization of WNV in vitro compared to the parent mammalian cell-produced E16 (mE16). A single dose of ΔXFpE16 or ΔXFpE16scFv-CH protected mice against WNV-induced mortality even 4 days after infection at equivalent rates as mE16. This study provides a detailed tandem comparison of the expression, structure and function of a therapeutic MAb and its single-chain variant produced in glycoengineered plants. Moreover, it demonstrates the development of anti-WNV MAb therapeutic variants that are equivalent in efficacy to pE16, simpler to produce, and likely safer to use as therapeutics due to their mammalian N-glycosylation. This platform may lead to a more robust and cost effective production of antibody-based therapeutics against WNV infection and other infectious, inflammatory, or neoplastic diseases.