Nithyadevi Duraisamy, Mohd Yasir Khan, Abid Ullah Shah, Reda Nacif Elalaoui, Mohammed Cherkaoui, Maged Gomaa Hemida
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These epitopes are believed to induce a robust immune response through the interaction with major histocompatibility complex (MHC class II) molecules (2) to design some novel BCoV multiepitope-based vaccines.</p><p><strong>Materials and methods: </strong>The goal is achieved through several integrated <i>in silico</i> prediction computational tools to map these epitopes within the major BCoV structural proteins. The final vaccine was constructed in conjugation with the Choleratoxin B toxin as an adjuvant. The tertiary structure of each vaccine construct was modeled through the AlphaFold2 tools. The constructed vaccine was linked to some immunostimulants such as Toll-like receptors (TLR2 and TLR4). We also predicted the affinity binding of these vaccines with this targeted protein using molecular docking. The stability and purity of each vaccine construct were assessed using the Ramachandran plot and the Z-score values. We created the <i>in silico</i> cloning vaccine constructs using various expression vectors through vector builder and Snap gene.</p><p><strong>Results and discussion: </strong>The average range of major BCoV structural proteins was detected within the range of 0.4 to 0.5, which confirmed their antigen and allergic properties. The binding energy values were detected between -7.9 and -9.4 eV and also confirmed their best interaction between our vaccine construct and Toll-like receptors. Our <i>in silico</i> cloning method expedited the creation of vaccine constructs and established a strong basis for upcoming clinical trials and experimental validations.</p><p><strong>Conclusion: </strong>Our designed multiepitope vaccine candidates per each BCoV structural protein showed high antigenicity, immunogenicity, non-allergic, non-toxic, and high-water solubility. 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引用次数: 0
摘要
导言:BCoV 是引起幼犊肠炎的重要原因之一,也可能是许多幼犊呼吸道疾病爆发的原因。BCoV 与其他细菌病原体共同参与了牛呼吸道疾病复合体的发病。我们的研究旨在(1)绘制 BCoV 主要结构蛋白中的免疫原表位(B 细胞和 T 细胞)。这些表位被认为能通过与主要组织相容性复合体(MHC II 类)分子的相互作用诱导强有力的免疫反应(2)设计出一些基于 BCoV 多表位的新型疫苗:该目标是通过几种集成的硅学预测计算工具来实现的,这些工具可绘制主要 BCoV 结构蛋白中的这些表位。最终的疫苗是与作为佐剂的霍乱毒素 B 结合制成的。每个疫苗构建体的三级结构都通过 AlphaFold2 工具进行了建模。构建的疫苗与一些免疫刺激剂(如 Toll 样受体(TLR2 和 TLR4))相连。我们还利用分子对接法预测了这些疫苗与这些靶蛋白的亲和力结合。我们利用拉马钱德兰图和 Z 值评估了每种疫苗构建体的稳定性和纯度。我们通过载体生成器和Snap基因使用各种表达载体创建了硅克隆疫苗构建体:检测到的主要 BCoV 结构蛋白的平均范围在 0.4 至 0.5 之间,这证实了它们的抗原性和过敏性。检测到的结合能值在-7.9至-9.4 eV之间,这也证实了我们的疫苗构建体与Toll样受体之间的最佳相互作用。我们的硅克隆方法加快了疫苗构建体的产生,为即将进行的临床试验和实验验证奠定了坚实的基础:结论:我们为每种 BCoV 结构蛋白设计的多位点候选疫苗具有高抗原性、免疫原性、无过敏性、无毒性和高水溶性。我们鼓励开展进一步研究,以验证这些新型 BCoV 疫苗在自然宿主中的有效性。
Machine learning tools used for mapping some immunogenic epitopes within the major structural proteins of the bovine coronavirus (BCoV) and for the in silico design of the multiepitope-based vaccines.
Introduction: BCoV is one of the significant causes of enteritis in young calves; it may also be responsible for many respiratory outbreaks in young calves. BCoV participates in the development of bovine respiratory disease complex in association with other bacterial pathogens. Our study aimed (1) to map the immunogenic epitopes (B and T cells) within the major BCoV structural proteins. These epitopes are believed to induce a robust immune response through the interaction with major histocompatibility complex (MHC class II) molecules (2) to design some novel BCoV multiepitope-based vaccines.
Materials and methods: The goal is achieved through several integrated in silico prediction computational tools to map these epitopes within the major BCoV structural proteins. The final vaccine was constructed in conjugation with the Choleratoxin B toxin as an adjuvant. The tertiary structure of each vaccine construct was modeled through the AlphaFold2 tools. The constructed vaccine was linked to some immunostimulants such as Toll-like receptors (TLR2 and TLR4). We also predicted the affinity binding of these vaccines with this targeted protein using molecular docking. The stability and purity of each vaccine construct were assessed using the Ramachandran plot and the Z-score values. We created the in silico cloning vaccine constructs using various expression vectors through vector builder and Snap gene.
Results and discussion: The average range of major BCoV structural proteins was detected within the range of 0.4 to 0.5, which confirmed their antigen and allergic properties. The binding energy values were detected between -7.9 and -9.4 eV and also confirmed their best interaction between our vaccine construct and Toll-like receptors. Our in silico cloning method expedited the creation of vaccine constructs and established a strong basis for upcoming clinical trials and experimental validations.
Conclusion: Our designed multiepitope vaccine candidates per each BCoV structural protein showed high antigenicity, immunogenicity, non-allergic, non-toxic, and high-water solubility. Further studies are highly encouraged to validate the efficacy of these novel BCoV vaccines in the natural host.
期刊介绍:
Frontiers in Veterinary Science is a global, peer-reviewed, Open Access journal that bridges animal and human health, brings a comparative approach to medical and surgical challenges, and advances innovative biotechnology and therapy.
Veterinary research today is interdisciplinary, collaborative, and socially relevant, transforming how we understand and investigate animal health and disease. Fundamental research in emerging infectious diseases, predictive genomics, stem cell therapy, and translational modelling is grounded within the integrative social context of public and environmental health, wildlife conservation, novel biomarkers, societal well-being, and cutting-edge clinical practice and specialization. Frontiers in Veterinary Science brings a 21st-century approach—networked, collaborative, and Open Access—to communicate this progress and innovation to both the specialist and to the wider audience of readers in the field.
Frontiers in Veterinary Science publishes articles on outstanding discoveries across a wide spectrum of translational, foundational, and clinical research. The journal''s mission is to bring all relevant veterinary sciences together on a single platform with the goal of improving animal and human health.