无细胞表达尼帕病毒跨膜蛋白以设计蛋白脂质体疫苗

Vivian T Hu, Shahrzad Ezzatpour, Ekaterina T Selivanovitch, Jordan Carter, Julie Sahler, Richard A Adeleke, Avery August, Hector Aguilar-Carreno, Susan Daniel, Neha P Kamat
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摘要

在包膜病毒表面表达的膜蛋白是疫苗中的强效抗原,但由于没有脂质支架而不稳定,因此很难生产和呈现。目前结合病毒膜蛋白的疫苗接种策略,如减毒活疫苗、灭活病毒或细胞外囊泡,都存在生产时间长、免疫原性差、加工步骤多和/或稳定性差等局限性。病毒膜蛋白的无细胞蛋白合成提供了一种快速、一步到位的方法,通过膜蛋白的共翻译折叠成纳米级脂质体来组装疫苗纳米颗粒。在这里,我们通过无细胞表达两种全长尼帕病毒膜蛋白,开发出一种针对致命尼帕病毒(NiV)的候选疫苗,尼帕病毒是一种被世界卫生组织列为优先病原体的高致死性病毒。我们证明了尼帕病毒融合蛋白(NiV F)和尼帕病毒糖蛋白(NiV G)都可以表达并共翻译整合到脂质体中,而且它们可以折叠成原生构象。我们发现,去除信号肽序列和改变脂质体的脂质成分可改善病毒膜蛋白的整合。此外,脂质佐剂--单磷脂 A(MPLA)可以很容易地添加到脂质体中,而不会破坏蛋白质-囊泡负载或蛋白质折叠构象。最后,我们证明,与空蛋白和单蛋白对照组相比,我们生成的脂质体制剂能增强小鼠的体液反应。这项工作建立了一个平台,可快速组装膜抗原并将其作为多价疫苗,从而快速应对各种新出现的致病威胁。
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Cell-free expression of Nipah virus transmembrane proteins for proteoliposome vaccine design
Membrane proteins expressed on the surface of enveloped viruses are potent antigens in a vaccine, yet are difficult to produce and present due to their instability without a lipid scaffold. Current vaccination strategies that incorporate viral membrane proteins, such as live attenuated viruses, inactivated viruses, or extracellular vesicles, have limitations including lengthy production time, poor immunogenicity, extensive processing steps, and/or poor stability. Cell-free protein synthesis of viral membrane proteins offers a rapid, one-step method to assemble vaccine nanoparticles via cotranslational folding of membrane proteins into nanoscale liposomes. Here, we develop a vaccine candidate for the deadly Nipah virus (NiV), a highly lethal virus listed by the World Health Organization as a priority pathogen, by cell-free expressing two full-length Nipah virus membrane proteins. We demonstrate that both NiV fusion protein (NiV F) and NiV glycoprotein (NiV G) can be expressed and cotranslationally integrated into liposomes and that they fold into their native conformation. We find the removal of a signal peptide sequence and alteration of liposome lipid composition improves viral membrane protein incorporation. Furthermore, a lipid adjuvant, monophosphoryl lipid A (MPLA), can be readily added to liposomes without disrupting protein-vesicle loading or protein folding conformations. Finally, we demonstrate that our generated liposomal formulations lead to enhanced humoral responses in mice compared to empty and single-protein controls. This work establishes a platform to quickly assemble and present membrane antigens as multivalent vaccines that will enable a rapid response to the broad range of emerging pathogenic threats.
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