Recombinant chimeric horsepox virus (TNX-801) is attenuated relative to vaccinia virus strains in both in vitro and in vivo models.

IF 3.7 2区生物学 Q2 MICROBIOLOGY

mSphere Pub Date : 2024-11-13 DOI:10.1128/msphere.00265-24

Stephanie V Trefry, Mayanka Awasthi, Christy N Raney, Amy L Cregger, Chase A Gonzales, Brittney L Layton, Robert N Enamorado, Nelson A Martinez, Deborah S Gohegan, Masoudeh Masoud-Bahnamiri, Jennifer Y Cho, Dawn M Myscofski, Tinoush Moulaei, Natasza E Ziółkowska, Scott J Goebel, Seth Lederman, Sina Bavari, Farooq Nasar

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引用次数: 0

Abstract

Recombinant chimeric horsepox virus (TNX-801) is a preclinical vaccine in development against mpox and smallpox. In this report, we investigated the potential phenotypic differences in in vitro and in vivo models between TNX-801 and older vaccinia virus (VACV)-based vaccine strains (VACV-Lis and VACV-NYCBH) used in the eradication of smallpox as well as VACV-WR, VACV-IHD, and MVA. TNX-801 displayed a small plaque phenotype (~1-2 mm) in BSC-40 and Vero-E6 cells. Multi-step replication kinetics in immortalized nonhuman primate cell lines, and human primary cells from dermal and respiratory tracts yielded >10- to 100-fold lower infectious titers than the VACV strains. In addition, the infectious particle-to-genome copy ratio data suggests that TNX-801 genome packaging is ~10- to 100-fold less efficient than the VACV strains and the potential mechanism of TNX-801 attenuation is at the packaging/egress stage. Lastly, the susceptibility to VACV and TNX-801 infection of three new immunocompromised murine models (C56BL/6 Ifnar^-/-, C56BL/6 Ifngr^-/-, and C56BL/6 Ifnar^-/-/Ifngr^-/-) was investigated. VACV strains were able to produce severe disease including decrease in body weight and temperature, as well as lethality in murine models via the intraperitoneal or intranasal routes. In contrast to VACV strains, TNX-801 was unable to produce any disease in murine models. These data demonstrate that TNX-801 is >10- to 1,000-fold more attenuated compared to older VACV-based smallpox vaccine strains in human primary cell lines and immunocompromised mice.

Importance: Variola and monkeypox viruses are medically important pathogens that can cause fatal human disease. The two FDA-approved vaccines, ACAM-2000 and JYNNEOS, have important advantages and disadvantages. ACAM-2000 offers durable immunity; however, it has high adverse event rates. In contrast, JYNNEOS has a safer profile but requires two doses 4-weeks apart to achieve comparable immunity. Consequently, there is a need for vaccines offering durable immunity via single immunization with minimal adverse events. TNX-801 is a preclinical stage vaccine that can stimulate potent immunity via a single dose and provides protection against lethal mpox disease in the nonhuman primate model. Here, we show that TNX-801 is >10- to 1,000-fold attenuated in in vitro and in vivo models including human primary cells and immunocompromised murine models than vaccine strains utilized in smallpox eradication. The natural attenuation of TNX-801 and its ability to induce protective immunity via a single vaccination are promising and warrants further development.

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重组嵌合型马痘病毒（TNX-801）在体外和体内模型中都比疫苗病毒株减毒。

重组嵌合马痘病毒（TNX-801）是一种正在开发的临床前疫苗，用于预防水痘和天花。在本报告中，我们研究了 TNX-801 与以前用于根除天花的疫苗株（VACV-Lis 和 VACV-NYCBH）以及 VACV-WR、VACV-IHD 和 MVA 在体外和体内模型中的潜在表型差异。TNX-801 在 BSC-40 和 Vero-E6 细胞中显示出小斑块表型（约 1-2 毫米）。在永生化的非人灵长类细胞系以及来自皮肤和呼吸道的人类原代细胞中，多步复制动力学产生的感染滴度比 VACV 株系低 10 到 100 倍。此外，感染性颗粒与基因组拷贝比数据表明，TNX-801基因组包装的效率比VACV毒株低10至100倍，TNX-801衰减的潜在机制是在包装/表达阶段。最后，研究了三种新的免疫受损小鼠模型（C56BL/6 Ifnar-/-、C56BL/6 Ifngr-/-和C56BL/6 Ifnar-/-/Ifngr-/-）对 VACV 和 TNX-801 感染的易感性。VACV 株系能够通过腹腔或鼻内途径在小鼠模型中产生严重疾病，包括体重和体温下降以及致死。与 VACV 株系相反，TNX-801 无法在小鼠模型中产生任何疾病。这些数据表明，在人类原代细胞系和免疫功能低下的小鼠中，TNX-801 的减毒效果比基于 VACV 的旧天花疫苗株高出 10 至 1000 倍：重要意义：天花和猴痘病毒是医学上重要的病原体，可导致致命的人类疾病。美国食品及药物管理局批准的两种疫苗--ACAM-2000 和 JYNNEOS--各有重要的优缺点。ACAM-2000 可提供持久免疫力，但不良反应率较高。相比之下，JYNNEOS 的安全性更高，但需要间隔 4 周注射两剂才能获得类似的免疫力。因此，需要通过单次免疫获得持久免疫力且不良反应最小的疫苗。TNX-801 是一种处于临床前阶段的疫苗，可通过单次剂量激发强大的免疫力，并在非人灵长类动物模型中提供对致命性 mpox 疾病的保护。在这里，我们展示了 TNX-801 在体外和体内模型（包括人类原代细胞和免疫力低下的小鼠模型）中的减毒效果，与根除天花时使用的疫苗株相比，TNX-801 的减毒效果>10-1000 倍。TNX-801 的自然减毒能力及其通过单次接种诱导保护性免疫的能力前景广阔，值得进一步开发。

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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来源期刊

mSphere Immunology and Microbiology-Microbiology

CiteScore

8.50

自引率

2.10%

发文量

192

审稿时长

11 weeks

期刊介绍： mSphere™ is a multi-disciplinary open-access journal that will focus on rapid publication of fundamental contributions to our understanding of microbiology. Its scope will reflect the immense range of fields within the microbial sciences, creating new opportunities for researchers to share findings that are transforming our understanding of human health and disease, ecosystems, neuroscience, agriculture, energy production, climate change, evolution, biogeochemical cycling, and food and drug production. Submissions will be encouraged of all high-quality work that makes fundamental contributions to our understanding of microbiology. mSphere™ will provide streamlined decisions, while carrying on ASM''s tradition for rigorous peer review.