Astbury Centre for Structural Molecular Biology, School of Molecular and Cellular Biology, Faculty of Biological Sciences, University of Leeds, Leeds, United Kingdom.
University of Reading, School of Biological Sciences, Reading, United Kingdom.
Microbiol Spectr. 2023 Feb 14;11(1):e0430022. doi: 10.1128/spectrum.04300-22. Epub 2022 Dec 12.
The production of enterovirus virus-like particles (VLPs) that lack the viral genome have great potential as vaccines for a number of diseases, such as poliomyelitis and hand, foot, and mouth disease. These VLPs can mimic empty capsids, which are antigenically indistinguishable from mature virions, produced naturally during viral infection. Both in infection and , capsids and VLPs are generated by the cleavage of the P1 precursor protein by a viral protease. Here, using a stabilized poliovirus 1 (PV-1) P1 sequence as an exemplar, we show the production of PV-1 VLPs in Pichia pastoris in the absence of the potentially cytotoxic protease, 3CD, instead using the porcine teschovirus 2A (P2A) peptide sequence to terminate translation between individual capsid proteins. We compare this to protease-dependent production of PV-1 VLPs. Analysis of all permutations of the order of the capsid protein sequences revealed that only VP3 could be tagged with P2A and maintain native antigenicity. Transmission electron microscopy of these VLPs reveals the classic picornaviral icosahedral structure. Furthermore, these particles were thermostable above 37°C, demonstrating their potential as next generation vaccine candidates for PV. Finally, we believe the demonstration that native antigenic VLPs can be produced using protease-independent methods opens the possibility for future enteroviral vaccines to take advantage of recent vaccine technological advances, such as adenovirus-vectored vaccines and mRNA vaccines, circumventing the potential problems of cytotoxicity associated with 3CD, allowing for the production of immunogenic enterovirus VLPs . The widespread use of vaccines has dramatically reduced global incidence of poliovirus infections over a period of several decades and now the wild-type virus is only endemic in Pakistan and Afghanistan. However, current vaccines require the culture of large quantities of replication-competent virus for their manufacture, thus presenting a potential risk of reintroduction into the environment. It is now widely accepted that vaccination will need to be extended posteradication into the foreseeable future to prevent the potentially catastrophic reintroduction of poliovirus into an immunologically naive population. It is, therefore, imperative that novel vaccines are developed which are not dependent on the growth of live virus for their manufacture. We have expressed stabilized virus-like particles in yeast, from constructs that do not require coexpression of the protease. This is an important step in the development of environmentally safe and commercially viable vaccines against polio, which also provides some intriguing insights into the viral assembly process.
缺乏病毒基因组的肠道病毒病毒样颗粒 (VLPs) 作为许多疾病(如脊髓灰质炎和手足口病)的疫苗具有很大的潜力。这些 VLPs 可以模拟空衣壳,这些衣壳在病毒感染过程中自然产生,在抗原上与成熟病毒粒子无法区分。在感染和非感染中,衣壳和 VLPs 都是由病毒蛋白酶切割 P1 前体蛋白产生的。在这里,我们使用稳定的脊髓灰质炎病毒 1 (PV-1) P1 序列作为范例,展示了在毕赤酵母中生产 PV-1 VLPs 的情况,在这种情况下,不使用潜在细胞毒性的蛋白酶 3CD,而是使用猪口蹄疫病毒 2A (P2A) 肽序列来终止单个衣壳蛋白之间的翻译。我们将这与依赖蛋白酶生产的 PV-1 VLPs 进行了比较。对衣壳蛋白序列顺序的所有排列进行分析表明,只有 VP3 可以用 P2A 标记并保持天然抗原性。对这些 VLPs 的透射电子显微镜分析显示出典型的小核糖核酸病毒二十面体结构。此外,这些颗粒在 37°C 以上具有热稳定性,表明它们有可能成为下一代脊髓灰质炎病毒疫苗候选物。最后,我们相信,证明可以使用非依赖于蛋白酶的方法生产天然抗原性 VLPs 为未来的肠道病毒疫苗开辟了可能性,可以利用最近的疫苗技术进步,如腺病毒载体疫苗和 mRNA 疫苗,规避与 3CD 相关的潜在细胞毒性问题,从而生产出具有免疫原性的肠道病毒 VLPs。疫苗的广泛使用在几十年的时间内显著降低了全球脊髓灰质炎病毒感染的发病率,现在野生型病毒仅在巴基斯坦和阿富汗流行。然而,目前的疫苗在制造过程中需要大量培养具有复制能力的病毒,因此存在重新引入环境的潜在风险。现在人们普遍认为,在可预见的未来,疫苗接种将需要在根除后继续进行,以防止脊髓灰质炎病毒潜在灾难性地重新引入到免疫幼稚人群中。因此,开发不依赖于活病毒生长的新型疫苗是当务之急。我们已经在酵母中表达了稳定的病毒样颗粒,这些颗粒的构建不需要共表达蛋白酶。这是开发针对脊髓灰质炎的环境安全和商业可行疫苗的重要一步,也为病毒组装过程提供了一些有趣的见解。
