A Chimeric Vaccine Consisting of Highly Immunogenic Regions Form Escherichia coli Iron Regulated Outer-Membrane Proteins: An In Silico Approach

Research in Molecular Medicine Pub Date : 2021-04-30 DOI:10.32598/rmm.9.2.3

F. Sefid, Mahsa Akbari Oryani, Maryam Mehdi, Z. Payandeh, S. Khalili, Ehsan Kaffash, G. Azamirad, S. Kalantar

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Abstract

Background: Six pathogen-associated Outer Membrane Iron receptors (OMPs) reside in Uropathogenic strains of E. coli (UPEC): haem-utilization gene (ChuA), Heme acquisition protein (Hma), IrgA homologue adhesin (Iha), Iron-regulated virulence gene (IreA), IroN, and IutA. Cumulative concern over the prevalence of this bacteria in hospital environments, especially in Intensive Care Units (ICUs), highlights the significance of vaccination against this pathogen. In this study, we aimed to develop 3D models of ChuA, Hma, IutA, IreA, Iha, and IroN proteins by invoking various in silico methods and design a chimeric immunogen composed of highly immunogenic regions from these six Escherichia coli antigens as a chimeric vaccine. Materials and Methods: In the present study, homology modeling, fold recognition, Ab initio approaches, and their combination were invoked to determine the Three-Dimensional (3D) structures of ChuA, Hma, Iha, IreA, IroN, and IutA. Next, a set of biochemical, immunological, and functional properties were predicted using various bioinformatics tools. Results: The obtained results indicated that all six modeled proteins fold to a β-barrel structure. The results of biochemical, immunological, and functional analysis determined the regions of each antigen carrying the best immunogenic properties. These regions are employed to construct the final vaccine linked via flexible GGGGS linkers. Intriguingly, re-analyzing the properties of the final vaccine indicated its immunological advantage over individual proteins. Conclusion: The strategy of this study to predict the protein 3D structure, followed by epitope prediction, could be adapted to design efficient vaccine candidates. Applying this approach, we designed a vaccine candidate harboring the most promising regions of six OMPs. This approach could lead to better functional, structural, and therapeutic outcomes in the context of vaccine design investigations.

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由大肠杆菌铁调控外膜蛋白的高免疫原性区域组成的嵌合疫苗:一种计算机方法

背景:大肠杆菌尿路致病性菌株(UPEC)中存在6种病原体相关的外膜铁受体(OMPs):血液利用基因(ChuA)、血红素获得蛋白(Hma)、IrgA同源粘附素(Iha)、铁调控毒力基因(IreA)、铁和IutA。对这种细菌在医院环境，特别是在重症监护病房(icu)中流行的累积关注，突出了针对这种病原体接种疫苗的重要性。在这项研究中，我们旨在利用各种硅方法建立ChuA, Hma, IutA, IreA, Iha和IroN蛋白的3D模型，并设计由这六种大肠杆菌抗原的高免疫原区组成的嵌合免疫原作为嵌合疫苗。材料和方法:本研究采用同源建模、折叠识别、从头算方法及其组合方法确定了ChuA、Hma、Iha、IreA、IroN和IutA的三维结构。接下来，使用各种生物信息学工具预测一组生化，免疫学和功能特性。结果:6种模型蛋白均折叠成β-桶状结构。生化、免疫学和功能分析的结果确定了每个抗原携带最佳免疫原性的区域。这些区域被用来构建通过柔性GGGGS连接体连接的最终疫苗。有趣的是，重新分析最终疫苗的特性表明，它比单个蛋白质具有免疫优势。结论:本研究预测蛋白质三维结构，然后预测表位的策略可用于设计有效的候选疫苗。应用这种方法，我们设计了一种候选疫苗，其中包含六个omp中最有希望的区域。在疫苗设计研究的背景下，这种方法可能导致更好的功能、结构和治疗结果。

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Research in Molecular Medicine

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21 weeks