Rice-produced Classical Swine Fever Virus Glycoprotein E2 with Herringbone-dimer Design to Enhance Immune Responses

Overview

Journal Plant Biotechnol J

Specialties Biology
Biotechnology

Date 2023 Aug 12

PMID 37572354

Authors

Qianru Xu

Fanshu Ma

Daichang Yang

Qingmei Li

Liming Yan

Jiquan Ou

Longxian Zhang

Yunchao Liu

Quan Zhan

Rui Li

Qiang Wei

Hui Hu

Yanan Wang

Xueyang Li

Shenli Zhang

Jifei Yang

Shujun Chai

Yongkun Du

Li Wang

Erqin Zhang

Gaiping Zhang

Affiliations

Soon will be listed here.

Abstract

Pestiviruses, including classical swine fever virus, remain a concern for global animal health and are responsible for major economic losses of livestock worldwide. Despite high levels of vaccination, currently available commercial vaccines are limited by safety concerns, moderate efficacy, and required high doses. The development of new vaccines is therefore essential. Vaccine efforts should focus on optimizing antigen presentation to enhance immune responses. Here, we describe a simple herringbone-dimer strategy for efficient vaccine design, using the classical swine fever virus E2 expressed in a rice endosperm as an example. The expression of rE2 protein was identified, with the rE2 antigen accumulating to 480 mg/kg. Immunological assays in mice, rabbits, and pigs showed high antigenicity of rE2. Two immunizations with 284 ng of the rE2 vaccine or one shot with 5.12 μg provided effective protection in pigs without interference from pre-existing antibodies. Crystal structure and small-angle X-ray scattering results confirmed the stable herringbone dimeric conformation, which had two fully exposed duplex receptor binding domains. Our results demonstrated that rice endosperm is a promising platform for precise vaccine design, and this strategy can be universally applied to other Flaviviridae virus vaccines.

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