Owen Leddy, Yuko Yuki, Mary Carrington, Bryan D Bryson, Forest M White
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引用次数: 0
Abstract
Vaccine-elicited T cell responses can contribute to immune protection against emerging infectious disease risks such as antimicrobials-resistant (AMR) microbial pathogens and viruses with pandemic potential, but rapidly identifying appropriate targets for T cell priming vaccines remains challenging. Mass spectrometry (MS) analysis of peptides presented on major histocompatibility complexes (MHCs) can identify potential targets for protective T cell responses in a proteome-wide manner. However, pathogen-derived peptides are outnumbered by self peptides in the MHC repertoire and may be missed in untargeted MS analyses. Here we present a novel approach, termed PathMHC, that uses computational analysis of untargeted MS data followed by targeted MS to discover novel pathogen-derived MHC peptides more efficiently than untargeted methods alone. We applied this workflow to identify MHC peptides derived from multiple microbes, including potential vaccine targets presented on MHC-I by human dendritic cells infected with Mycobacterium tuberculosis. PathMHC will facilitate antigen discovery campaigns for vaccine development.
疫苗诱导的 T 细胞反应有助于提供免疫保护,抵御新出现的传染病风险,如抗菌素耐药 (AMR) 微生物病原体和具有大流行潜力的病毒,但快速确定 T 细胞诱导疫苗的适当靶点仍具有挑战性。对主要组织相容性复合体(MHC)上呈现的肽进行质谱分析,可以在整个蛋白质组范围内确定保护性 T 细胞反应的潜在靶点。然而,病原体衍生肽的数量超过了主要组织相容性复合物中自身肽的数量,可能会在非靶向 MS 分析中被漏掉。在这里,我们提出了一种称为 PathMHC 的新方法,它利用对非靶向 MS 数据的计算分析,然后再进行靶向 MS 分析,从而比单独使用非靶向方法更有效地发现新型病原体衍生的 MHC 肽。我们将这一工作流程用于鉴定来自多种微生物的 MHC 肽,包括感染结核分枝杆菌的人类树突状细胞在 MHC-I 上呈现的潜在疫苗靶标。PathMHC 将促进疫苗开发的抗原发现活动。