针对 Epstein-Barr 病毒的 mRNA 疫苗设计:一种免疫形式化方法。

In silico pharmacology Pub Date : 2024-07-24 eCollection Date: 2024-01-01 DOI:10.1007/s40203-024-00244-x
Elijah Kolawole Oladipo, Temitope Michael Akinleye, Stephen Feranmi Adeyemo, Modinat Wuraola Akinboade, Kehinde Favour Siyanbola, Victoria Ademide Adetunji, Olukayode Abimbola Arowosegbe, Victoria Kehinde Olatunji, Esther Oluwadarasimi Adaramola, Hezekiah Omotayo Afolabi, Christianah Damilola Ajani, Taiwo Pleasure Siyanbola, Elizabeth Oluwatoyin Folakanmi, Boluwatife Ayobami Irewolede, Olalekan John Okesanya, Olumide Faith Ajani, Olumuyiwa Elijah Ariyo, Esther Moradeyo Jimah, Bamidele Abiodun Iwalokun, Olatunji Matthew Kolawole, Julius Kola Oloke, Helen Onyeaka
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摘要

爱泼斯坦-巴氏病毒(EBV)在结构上与其他疱疹病毒相似,会引起传染性单核细胞增多症,并与多种癌症相关,因此对全球健康构成重大挑战。由于其影响广泛,有效的信使 RNA (mRNA) 疫苗对遏制其传播至关重要,这进一步凸显了开发这种疫苗的必要性。本研究采用免疫形式化方法,旨在通过选择抗原蛋白、预测线性 B 细胞表位、细胞毒性 T 细胞淋巴细胞 (CTL) 和辅助 T 细胞淋巴细胞 (HTL) 表位以及评估疫苗特性,设计一种全面的 EBV mRNA 疫苗。对来自不同地理区域的 79 个 EBV 分离物进行了研究。此外,还分析了疫苗构建体的理化特性、跨膜域、可溶性和二级结构。与 Toll-Like Receptor 5(TLR-5)进行了分子对接。对选定的主要组织相容性复合体(MHC)等位基因的群体覆盖率进行了评估,并模拟了免疫反应。研究结果表明,该疫苗具有高抗原性、无毒性和无过敏性,并具有良好的理化特性。疫苗的三维结构类似于原生结构,能与 TLR-5 强结合,表明疫苗与 TLR-5 有很好的亲和力。所选的 MHC 等位基因提供了 89.1% 的广泛通用人群覆盖率,免疫模拟显示了强大而广泛的免疫原反应,激活了关键的免疫细胞、抗体和细胞因子。这些发现为进一步开发和测试 EBV 候选疫苗奠定了坚实的基础,为抗击 EBV 感染提供了潜在的解决方案。
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mRNA vaccine design for Epstein-Barr virus: an immunoinformatic approach.

Epstein-Barr Virus (EBV), structurally similar to other herpes viruses, possess significant global health challenges as it causes infectious mononucleosis and is also associated with various cancers. Due to this widespread impact, an effective messenger RNA (mRNA) vaccine is paramount to help curb its spread, further underscoring the need for its development. This study, following an immunoinformatic approach, aimed to design a comprehensive mRNA vaccine against the EBV by selecting antigenic proteins, predicting Linear B-cell epitopes, cytotoxic T-cell lymphocyte (CTL) and helper T-cell lymphocyte (HTL) epitopes, and assessing vaccine characteristics. Seventy-nine EBV isolates from diverse geographical regions were examined. Additionally, the vaccine construct's physicochemical properties, transmembrane domains, solubility, and secondary structures were analysed. Molecular docking was conducted with Toll-Like Receptor 5 (TLR-5). Population coverage was assessed for selected major histocompatibility complex (MHC) alleles, and immune response was simulated. The result of this study highlighted a vaccine construct with high antigenicity, non-toxicity, and non-allergenicity and possessed favourable physicochemical properties. The vaccine's 3D structure is native-like and strongly binds with TLR-5, indicating a solid affinity with TLR-5. The selected MHC alleles provided broad universal population coverage of 89.1%, and the immune simulations suggested a robust and wide-ranging immunogenic response, activating critical immune cells, antibodies, and cytokines. These findings provide a solid foundation for further development and testing of the EBV candidate vaccine, offering potential solutions for combating EBV infections.

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