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口服免疫 HIV-1 包膜 SOSIP 三聚体可在非人类灵长类动物中引发全身性免疫反应和交叉反应性抗 V1V2 抗体。

Oral Immunization with HIV-1 Envelope SOSIP trimers elicits systemic immune responses and cross-reactive anti-V1V2 antibodies in non-human primates.

机构信息

Seattle Children's Research Institute, Seattle, WA, United States of America.

Washington National Primate Research Center, University of Washington, Seattle, WA, United States of America.

出版信息

PLoS One. 2020 May 29;15(5):e0233577. doi: 10.1371/journal.pone.0233577. eCollection 2020.

DOI:10.1371/journal.pone.0233577
PMID:32470041
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC7259690/
Abstract

Development of a successful HIV vaccine is dependent upon a determination of the optimum antigen and adjuvant as well as choosing an optimal site for vaccine delivery. The site of delivery is particularly relevant as HIV transmission generally requires that the virus crosses a mucosal membrane to infect a new host. Here we undertake a pilot study comparing three vaccine delivery routes, two to the oral cavity (intraepithelial (iEp) and needle-free (NF-Injex)) as well as intramuscular (IM) delivery. These vaccinations utilized a recombinant HIV-1 Env trimer 10042.05 from an elite neutralizer, subject VC10042, that has previously induced high titers of cross-clade reactive V1V2 antibodies. The 10042.05.SOSIP fused trimer was administered with adjuvants R848 (Resiquimod), MPLA and Alhydrogel to characterize the innate cellular and anti-HIV Envelope (Env) antibody responses following the administration of the vaccine to the oral mucosa. Oral delivery of the 10042.05.SOSIP induced high titers of anti-V1V2 antibodies, which together with previous studies, indicates an immunogenic bias toward the V1V2 regions in 10042-derived Envs. Both types of oral vaccine delivery resulted in immunologic and serologic responses that were comparable to the IM delivery route. Furthermore, induction of anti-V1-V2 specific antibodies was best following iEp delivery of the oral vaccine identifying this as the optimal method to orally deliver this vaccine formulation.

摘要

开发成功的 HIV 疫苗取决于确定最佳抗原和佐剂,以及选择疫苗接种的最佳部位。接种部位尤为重要,因为 HIV 传播通常需要病毒穿过黏膜膜感染新宿主。在这里,我们进行了一项初步研究,比较了三种疫苗接种途径,两种途径是口腔内(上皮内(iEp)和无针(NF-Injex))以及肌肉内(IM)接种。这些疫苗接种使用了来自精英中和剂 VC10042 的重组 HIV-1 Env 三聚体 10042.05,该三聚体先前诱导了高滴度的跨谱系反应性 V1V2 抗体。10042.05.SOSIP 融合三聚体与佐剂 R848(Resiquimod)、MPLA 和 Alhydrogel 一起给药,以描述疫苗接种到口腔黏膜后固有细胞和抗 HIV Envelope(Env)抗体反应。10042.05.SOSIP 的口腔给药诱导了高滴度的抗 V1V2 抗体,这与之前的研究一起表明,在 10042 衍生的 Envs 中存在对 V1V2 区域的免疫原性偏向。两种类型的口腔疫苗接种都导致了与 IM 接种途径相当的免疫和血清学反应。此外,口腔疫苗 iEp 接种后诱导的抗 V1-V2 特异性抗体最好,这表明这是口服接种这种疫苗制剂的最佳方法。

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3
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4
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5
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