抗原
免疫系统
埃利斯波特
非洲猪瘟病毒
病毒学
接种疫苗
佐剂
生物
抗体
免疫
微生物学
体液免疫
免疫学
T细胞
病毒
作者
Lidan Sun,Jinsong Zhang,Lijun Shi,Yuanli Peng,Xiangning Feng,Fang Huang,Feixia Yang,Jinyu Li,Shuo Wang,Jingqi Niu,Jinling Liu,Yingjun Li,Shanhu Li,Zeliang Chen
标识
DOI:10.1021/acsabm.3c01035
摘要
African swine fever is an acute and highly contagious infectious disease with a mortality rate of up to 100%. The lack of commercial vaccines and drugs is a serious economic threat to the global pig industry. Cell-mediated immunity plays an essential role in protection against viral infection. We previously reported the rational design of a T-cell-activating thermostable scaffold (RPT) for antigen delivery and improved cellular immunity. We conjugated antigens P30, P54, P72, CD2 V, and CP312R to RPT, using a SpyCatcher/SpyTag covalent attachment strategy to construct nanovaccines (multiantigens-RPT). Multiantigens-RPT exhibited significantly higher thermal, storage, and freeze–thaw stability. The specific antibodies IgG and IgG2a of the multiantigen-RPT-immunized were higher than the antigens cocktail-immunized by approximately 10–100 times. ELISpot demonstrated that more IFN-γ-secreting cells were produced by the multiantigen-RPT-immunized than by the antigens cocktail-immunized. Delivery of the multiantigen nanovaccine by a T-cell-activating scaffold induced strong humoral and cellular immune responses in mice and pigs and is a potentially useful candidate vaccine for the African swine fever virus.
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