Wang Weijun, Ma Zihan, Lou Qiuli, Li Tingting, Huang Zhaoying, Yin Wen, Lou Chunbo, Xiang Yanhui
Center for Cell and Gene Circuit Design, CAS Key Laboratory of Quantitative Synthetic Biology, Shenzhen Institute of Synthetic Biology, Shenzhen Institutes of Advanced Technology, Chinese Academy of Sciences, Shenzhen 518055, China.
University of Chinese Academy of Sciences, Beijing 100049, China.
Chem Bio Eng. 2025 Jun 9;2(8):475-484. doi: 10.1021/cbe.5c00030. eCollection 2025 Aug 28.
Influenza remains a highly contagious respiratory disease with profound global health and economic implications. Although traditional vaccines, including inactivated influenza vaccines (IIVs), live attenuated influenza vaccines (LAIVs), and recombinant subunit influenza vaccines (RIVs), are widely available, their efficacy against emerging viral strains is often limited. This limitation underscores the urgent need for novel vaccine strategies. In this study, we explored both DNA and RNA vaccine platforms for influenza, utilizing phage RNA polymerase (RNAP) and the capping enzyme NP868R. For the influenza DNA vaccine strategy, we employed a phage RNAP-dependent positive feedback transcription system to achieve high-efficiency expression of the influenza hemagglutinin (HA) antigen. Utilizing the transcription mechanism dependent on phage RNAP polymerase, our DNA vaccine strategy confines antigen transcription and translation within the cytoplasm, thereby reducing the risk of genomic integration inherent to conventional DNA vaccines. In parallel, for the influenza RNA vaccine, we developed a replication-deficient vesicular stomatitis virus (rdVSV) expressing HA as a self-amplifying RNA vaccine. By replacing the traditional T7 vaccinia virus with T7 RNAP fused to a capping enzyme in the rdVSV rescue process, we achieved a high titer of 1.2 × 10 PFU/mL in a single round of rescue. This modification not only shortened the time required for recombinant VSV (rdVSV) rescue but also mitigated the safety concerns associated with T7 vaccinia virus usage. Moreover, this innovation facilitates faster RNA vaccine production, reduces manufacturing costs, and relaxes environmental requirements for RNA vaccine production. In animal studies, BALB/c mice immunized with the DNA vaccine exhibited significantly enhanced HA protein expression and higher antibody titers when dendritic cells (DCs) were employed as delivery carriers. Similarly, RNA vaccine immunized mice exhibited robust humoral and cellular immune responses, marked by increased HA-specific IgG levels and elevated cytokine production. These findings highlight the potential of both platforms as versatile tools for rapidly responding to emerging pathogens and advancing vaccine design for infectious diseases and therapeutic applications. With further technological optimization and clinical validation, this strategy is expected to provide a promising new solution for influenza prevention and control.
流感仍然是一种具有高度传染性的呼吸道疾病,对全球健康和经济有着深远影响。尽管传统疫苗,包括灭活流感疫苗(IIV)、减毒活流感疫苗(LAIV)和重组亚单位流感疫苗(RIV)广泛可得,但它们对新出现的病毒株的效力往往有限。这一局限性凸显了对新型疫苗策略的迫切需求。在本研究中,我们探索了用于流感的DNA和RNA疫苗平台,利用噬菌体RNA聚合酶(RNAP)和加帽酶NP868R。对于流感DNA疫苗策略,我们采用了一种依赖噬菌体RNAP的正反馈转录系统,以实现流感血凝素(HA)抗原的高效表达。利用依赖噬菌体RNAP聚合酶的转录机制,我们的DNA疫苗策略将抗原转录和翻译限制在细胞质内,从而降低了传统DNA疫苗固有的基因组整合风险。同时,对于流感RNA疫苗,我们开发了一种表达HA的复制缺陷型水疱性口炎病毒(rdVSV)作为自我扩增RNA疫苗。通过在rdVSV拯救过程中用与加帽酶融合的T7 RNAP取代传统的T7痘苗病毒,我们在一轮拯救中获得了1.2×10 PFU/mL的高滴度。这一改进不仅缩短了重组VSV(rdVSV)拯救所需的时间,还减轻了与使用T7痘苗病毒相关的安全担忧。此外,这一创新促进了更快的RNA疫苗生产,降低了制造成本,并放宽了RNA疫苗生产的环境要求。在动物研究中,当使用树突状细胞(DC)作为递送载体时,用DNA疫苗免疫的BALB/c小鼠表现出HA蛋白表达显著增强和抗体滴度更高。同样,用RNA疫苗免疫的小鼠表现出强大的体液和细胞免疫反应,其特征是HA特异性IgG水平增加和细胞因子产生升高。这些发现突出了这两个平台作为快速应对新出现病原体以及推进传染病疫苗设计和治疗应用的通用工具的潜力。随着进一步的技术优化和临床验证,这一策略有望为流感预防和控制提供一个有前景的新解决方案。
