Optimising a linear ‘Doggybone’ DNA vaccine for influenza virus through the incorporation of DNA targeting sequences and neuraminidase antigen

Discovery immunology Pub Date : 2024-01-03 DOI:10.1093/discim/kyad030

Robert F. Cunliffe, David C. Stirling, Ilaria Razzano, Valarmathy Murugaiah, E. Montomoli, Sungwon Kim, Madina Wane, Helen Horton, Lisa J. Caproni, J. Tregoning

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Abstract

Influenza virus represents a challenge for traditional vaccine approaches due to its seasonal changes and potential for zoonotic transmission. Nucleic acid vaccines can overcome some of these challenges, especially through the inclusion of multiple antigens to increase breadth of response. RNA vaccines were an important part of the response to the COVID-19 pandemic, but for future outbreaks DNA vaccines may have some advantages in terms of stability and manufacturing cost that warrant continuing investigation to fully realise their potential. Here we investigate influenza virus vaccines made using a closed loop linear DNA platform, Doggybone™ DNA (dbDNA), produced by a rapid and scalable cell-free method. Influenza vaccines have mostly focussed on Haemagglutinin (HA), but the inclusion of Neuraminidase (NA) may provide additional protection. Here we explored the potential of including NA in a dbDNA vaccine, looking at DNA optimisation, mechanism and breadth of protection. We showed that DNA targeting sequences (DTS) improved immune responses against HA but not NA. We explored whether NA vaccine induced protection against influenza virus infection was cell mediated but depletion of CD8 and NK cells made no impact, suggesting it was antibody mediated. This is reflected in restriction of protection only homologous strains of influenza virus. Importantly, we saw that including both HA and NA in a single combined vaccine did not dampen the immune response to either one. Overall, we show that linear dbDNA can induce an immune response against NA which may offer increased protection in instances of HA mismatch where NA remains more conserved.

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通过加入 DNA 靶向序列和神经氨酸酶抗原优化流感病毒线性 "Doggybone "DNA 疫苗

流感病毒因其季节性变化和人畜共患传播的可能性而对传统疫苗方法构成挑战。核酸疫苗可以克服其中的一些挑战，特别是通过加入多种抗原来提高反应的广度。RNA 疫苗是应对 COVID-19 大流行的重要组成部分，但对于未来的疫情爆发，DNA 疫苗在稳定性和制造成本方面可能有一些优势，需要继续研究以充分发挥其潜力。在此，我们研究了使用闭环线性 DNA 平台 Doggybone™ DNA（dbDNA）制造的流感病毒疫苗，这种疫苗是通过快速、可扩展的无细胞方法生产的。流感疫苗主要集中在血凝素（HA）上，但加入神经氨酸酶（NA）可提供额外的保护。在此，我们探讨了在 dbDNA 疫苗中加入 NA 的可能性，研究了 DNA 的优化、机制和保护范围。我们发现，DNA靶向序列（DTS）能提高对HA的免疫反应，但不能提高对NA的免疫反应。我们探讨了 NA 疫苗诱导的流感病毒感染保护是否是细胞介导的，但 CD8 和 NK 细胞的耗竭没有产生任何影响，这表明它是抗体介导的。这反映在保护范围仅限于流感病毒的同源毒株。重要的是，我们发现在单一联合疫苗中同时包含 HA 和 NA 并不会削弱对其中任何一种的免疫反应。总之，我们的研究表明，线性 dbDNA 可以诱导针对 NA 的免疫反应，这可能会在 HA 错配的情况下提供更强的保护，因为 NA 仍然更为保守。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Discovery immunology

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