免疫信息学方法设计抗惠特莫尔病嵌合疫苗

Q3 Computer Science Open Bioinformatics Journal Pub Date : 2023-10-20 DOI:10.2174/0118750362253383230922100803
Shalini Maurya, Salman Akhtar, Mohammad Kalim Ahmad Khan
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引用次数: 0

摘要

目的:耐多药假马利氏伯克氏菌具有显著的发病率和死亡率。因此,需要一种针对这种病原体的疫苗。利用减法蛋白质组学和反向疫苗学方法,我们设计了一种针对病原体的嵌合多表位疫苗。方法:采用减法蛋白质组学方法提取21个非冗余病原体蛋白质组。在这些蛋白质中,通过各种分析,我们发现了与人类非同源的、必需的、有毒的蛋白质。针对PDB数据库的BLASTp和Pocket药物分析获得了9个具有3D结构且可药物的蛋白质。通过亚细胞定位和抗原性预测鉴定出4种可能作为疫苗候选蛋白,它们可用于反向疫苗学方法来制造嵌合多表位疫苗。结果:利用在线资源和服务器,确定了MHC I类、II类和B细胞表位。预测的表位是根据毒性、溶解度、过敏原性和亲水性分析选择的。这些预测的表位具有免疫原性,用于构建多价嵌合疫苗。抗原表位、佐剂、连接体和PADRE氨基酸序列被用来制造疫苗。从对接和分子动力学模拟中可以看出,入围的疫苗构建体也与HLA等位基因和TLR4相互作用。因此,疫苗构建体V1可以引发针对假马利氏伯克氏菌的免疫应答。结论:假假芽孢杆菌蛋白质组的可用性使本研究通过各种计算机方法成为可能。我们可以利用减法蛋白质组学筛选疫苗靶点,然后利用反向疫苗学和免疫信息学方法构建嵌合疫苗。
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Immunoinformatics Approach for the Design of Chimeric Vaccine Against Whitmore Disease
Purpose: Multidrug-resistant Burkholderia pseudomallei is associated with significant morbidity and mortality. Hence, there is a requirement for a vaccine for this pathogen. Using subtractive proteomics and reverse vaccinology approaches, we have designed a chimeric multiepitope vaccine against the pathogen in the present study. Methods: Twenty-one non-redundant pathogen proteomes were mined using a subtractive proteomics strategy. Out of these, by various analyses, we found proteins that were non-homologous to humans, essential, and virulent. BLASTp against the PDB database and Pocket druggability analysis yielded nine proteins whose 3D structure is available and are druggable. Four proteins that could be candidates for vaccines were identified by subcellular localization and antigenicity prediction, and they could be used in reverse vaccinology methods to create a chimeric multiepitope vaccine. Results: Using online resources and servers, MHC class I, II, and B cell epitopes were identified. The predicted epitopes were selected based on analysis of toxicity, solubility, allergenicity, and hydrophilicity. These predicted epitopes, which were immunogenic, were used for the construction of a multivalent chimeric vaccine. The epitopes, adjuvants, linkers, and PADRE amino acid sequences were employed to create the vaccine. Shortlisted vaccine constructs also interact with the HLA allele and TLR4, as evident from docking and molecular dynamics simulation. Thus, vaccine construct V1 can elicit an immune response against Burkholderia pseudomallei . Conclusion: The availability of the proteome of B. pseudomallei has made this study possible through the usage of various in silico approaches. We could shortlist vaccine targets using subtractive proteomics and then construct chimeric vaccines using reverse vaccinology and immunoinformatics approaches.
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来源期刊
Open Bioinformatics Journal
Open Bioinformatics Journal Computer Science-Computer Science (miscellaneous)
CiteScore
2.40
自引率
0.00%
发文量
4
期刊介绍: The Open Bioinformatics Journal is an Open Access online journal, which publishes research articles, reviews/mini-reviews, letters, clinical trial studies and guest edited single topic issues in all areas of bioinformatics and computational biology. The coverage includes biomedicine, focusing on large data acquisition, analysis and curation, computational and statistical methods for the modeling and analysis of biological data, and descriptions of new algorithms and databases. The Open Bioinformatics Journal, a peer reviewed journal, is an important and reliable source of current information on the developments in the field. The emphasis will be on publishing quality articles rapidly and freely available worldwide.
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