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المؤلفAbbas, Khan
المؤلفAli, Syed Shujait
المؤلفKhan, Asghar
المؤلفZahid, Muhammad Ammar
المؤلفAlshabrmi, Fahad M.
المؤلفWaheed, Yasir
المؤلفAgouni, Abdelali
تاريخ الإتاحة2024-08-27T07:17:18Z
تاريخ النشر2024-09-30
اسم المنشورMicrobial Pathogenesis
المعرّفhttp://dx.doi.org/10.1016/j.micpath.2024.106777
الرقم المعياري الدولي للكتاب08824010
معرّف المصادر الموحدhttps://www.sciencedirect.com/science/article/pii/S0882401024002444
معرّف المصادر الموحدhttp://hdl.handle.net/10576/58059
الملخصFrancisella tularensis can cause severe disease in humans via the respiratory or cutaneous routes and a case fatality ratio of up to 10 % is reported due to lack of proper antibiotic treatment, while F. novicida causes disease in severely immunocompromised individuals. Efforts are needed to develop effective vaccine candidates against Francisella species. Thus, in this study, a systematic computational work frame was used to deeply investigate the whole proteome of Francisella novicida containing 1728 proteins to develop vaccine against F. tularensis and related species. Whole-proteome analysis revealed that four proteins including (A0Q492) (A0Q7Y4), (A0Q4N4), and (A0Q5D9) are the suitable vaccine targets after the removal of homologous, paralogous and prediction of subcellular localization. These proteins were used to predict the T cell, B cell, and HTL epitopes which were joined together through suitable linkers to construct a multi-epitopes vaccine (MEVC). The MEVC was found to be highly immunogenic and non-allergenic while the physiochemical properties revealed the feasible expression and purification. Moreover, the molecular interaction of MEVC with TLR2, molecular simulation, and binding free energy analyses further validated the immune potential of the construct. According to Jcat analysis, the refined sequence demonstrates GC contents of 41.48 % and a CAI value of 1. The in-silico cloning and optimization process ensured compatibility with host codon usage, thereby facilitating efficient expression. Computational immune simulation studies underscored the capacity of MEVC to induce both primary and secondary immune responses. The conservation analysis further revealed that the selected epitopes exhibit 100 % conservation across different species and thus provides wider protection against Francisella.
راعي المشروعThis work was supported by the Qatar National Research Fund [grant No. NPRP14S-0406-210150] and Qatar University grant No. QUPD-CPH-23/24–592. The statements made herein are solely the responsibility of the authors.
اللغةen
الناشرElsevier
الموضوعFrancisella novicida
Subtractive proteomics
Vaccines
In silico cloning
Immune simulation
العنوانStructural proteomics guided annotation of vaccine targets and designing of multi-epitopes vaccine to instigate adaptive immune response against Francisella tularensis
النوعArticle
رقم المجلد194
ESSN1096-1208
dc.accessType Full Text


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