Maxime Cochin, Jean-Sélim Driouich, Grégory Moureau, Géraldine Piorkowski, Xavier de Lamballerie, Antoine Nougairède
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引用次数: 0
摘要
反向遗传系统主要用于挽救细胞培养中的重组病毒株。我们之前开发了 "感染性亚基因组扩增子"(ISA)方法,通过转染重叠的亚基因组 DNA 片段在体外挽救单链正义 RNA 病毒。在这里,我们提供了接种亚基因组扩增子后在体内直接产生感染性颗粒的概念验证。首先,我们在小鼠体内拯救了一株蜱传脑炎病毒,在体内转染 ISA 方法。使用 3 片段反向遗传学系统扩增亚基因组 DNA 片段,并将其肌肉注射到动物体内。当接种的 DNA 数量至少为 20µg 时,几乎所有动物都受到了感染。随后,我们对程序进行了优化,以提高动物感染率。为此,我们增加了电穿孔步骤和/或使用简化的 2 片段反向遗传系统。在最佳条件下,绝大多数动物的 DNA 感染剂量为 20ng。最后,我们将这种方法应用于日本脑炎和基孔肯雅病毒,证明了它的多功能性。此外,在开发 DNA 发射减毒活疫苗的背景下,这种新方法可促进体内减毒株的产生。它还能提供不含任何载体 DNA 的物质,这似乎是开发人类疫苗的一个重要标准。
In vivo rescue of arboviruses directly from subgenomic DNA fragments.
Reverse genetic systems are mainly used to rescue recombinant viral strains in cell culture. These tools have also been used to generate, by inoculating infectious clones, viral strains directly in living animals. We previously developed the "Infectious Subgenomic Amplicons" (ISA) method, which enables the rescue of single-stranded positive sense RNA viruses in vitro by transfecting overlapping subgenomic DNA fragments. Here, we provide proof-of-concept for direct in vivo generation of infectious particles following the inoculation of subgenomic amplicons. First, we rescued a strain of tick-borne encephalitis virus in mice to transpose the ISA method in vivo. Subgenomic DNA fragments were amplified using a 3-fragment reverse genetics system and inoculated intramuscularly. Almost all animals were infected when quantities of DNA inoculated were at least 20 µg. We then optimized our procedure in order to increase the animal infection rate. This was achieved by adding an electroporation step and/or using a simplified 2- fragment reverse genetics system. Under optimal conditions, a large majority of animals were infected with doses of 20 ng of DNA. Finally, we demonstrated the versatility of this method by applying it to Japanese encephalitis and Chikungunya viruses. This method provides an efficient strategy for in vivo rescue of arboviruses. Furthermore, in the context of the development of DNA-launched live attenuated vaccines, this new approach may facilitate the generation of attenuated strains in vivo. It also enables to deliver a substance free of any vector DNA, which seems to be an important criterion for the development of human vaccines.
期刊介绍:
Emerging Microbes & Infections is a peer-reviewed, open-access journal dedicated to publishing research at the intersection of emerging immunology and microbiology viruses.
The journal's mission is to share information on microbes and infections, particularly those gaining significance in both biological and clinical realms due to increased pathogenic frequency. Emerging Microbes & Infections is committed to bridging the scientific gap between developed and developing countries.
This journal addresses topics of critical biological and clinical importance, including but not limited to:
- Epidemic surveillance
- Clinical manifestations
- Diagnosis and management
- Cellular and molecular pathogenesis
- Innate and acquired immune responses between emerging microbes and their hosts
- Drug discovery
- Vaccine development research
Emerging Microbes & Infections invites submissions of original research articles, review articles, letters, and commentaries, fostering a platform for the dissemination of impactful research in the field.
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