An In Silico Multi-epitopes Vaccine Ensemble and Characterization Against Nosocomial Proteus penneri.

IF 2.4 4区 生物学 Q3 BIOCHEMISTRY & MOLECULAR BIOLOGY Molecular Biotechnology Pub Date : 2024-12-01 Epub Date: 2023-11-07 DOI:10.1007/s12033-023-00949-y
Asad Ullah, Bushra Rehman, Saifullah Khan, Taghreed N Almanaa, Yasir Waheed, Muhammad Hassan, Tahira Naz, Mehboob Ul Haq, Riaz Muhammad, Samira Sanami, Muhammad Irfan, Sajjad Ahmad
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Abstract

Proteus penneri (P. penneri) is a bacillus-shaped, gram-negative, facultative anaerobe bacterium that is primarily an invasive pathogen and the etiological agent of several hospital-associated infections. P. penneri strains are naturally resistant to macrolides, amoxicillin, oxacillin, penicillin G, and cephalosporins; in addition, no vaccines are available against these strains. This warrants efforts to propose a theoretical based multi-epitope vaccine construct to prevent pathogen infections. In this research, reverse vaccinology bioinformatics and immunoinformatics approaches were adopted for vaccine target identification and construction of a multi-epitope vaccine. In the first phase, a core proteome dataset of the targeted pathogen was obtained using the NCBI database and subjected to bacterial pan-genome analysis using bacterial pan-genome analysis (BPGA) to predict core protein sequences which were then used to find good vaccine target candidates. This identified two proteins, Hcp family type VI secretion system effector and superoxide dismutase family protein, as promising vaccine targets. Afterward using the IEDB database, different B-cell and T-cell epitopes were predicted. A set of four epitopes "KGSVNVQDRE, NTGKLTGTR, IIHSDSWNER, and KDGKPVPALK" were chosen for the development of a multi-epitope vaccine construct. A 183 amino acid long vaccine design was built along with "EAAAK" and "GPGPG" linkers and a cholera toxin B-subunit adjuvant. The designed vaccine model comprised immunodominant, non-toxic, non-allergenic, and physicochemical stable epitopes. The model vaccine was docked with MHC-I, MHC-II, and TLR-4 immune cell receptors using the Cluspro2.0 web server. The binding energy score of the vaccine was - 654.7 kcal/mol for MHC-I, - 738.4 kcal/mol for MHC-II, and - 695.0 kcal/mol for TLR-4. A molecular dynamic simulation was done using AMBER v20 package for dynamic behavior in nanoseconds. Additionally, MM-PBSA binding free energy analysis was done to test intermolecular binding interactions between docked molecules. The MM-GBSA net binding energy score was - 148.00 kcal/mol, - 118.00 kcal/mol, and - 127.00 kcal/mol for vaccine with TLR-4, MHC-I, and MHC-II, respectively. Overall, these in silico-based predictions indicated that the vaccine is highly promising in terms of developing protective immunity against P. penneri. However, additional experimental validation is required to unveil the real immune response to the designed vaccine.

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一种针对医院感染的penneri变形杆菌的硅内多表位疫苗集合和特性。
宾夕法尼亚变形杆菌(P.penneri)是一种芽孢杆菌形状的革兰氏阴性兼性厌氧细菌,主要是一种侵袭性病原体,也是几种医院相关感染的病原体。P.penneri菌株对大环内酯类、阿莫西林、苯唑西林、青霉素G和头孢菌素具有天然耐药性;此外,目前还没有针对这些菌株的疫苗。这就需要努力提出一种基于理论的多表位疫苗构建体来预防病原体感染。本研究采用反向疫苗学-生物信息学和免疫信息学方法进行疫苗靶点鉴定和构建多表位疫苗。在第一阶段,使用NCBI数据库获得靶向病原体的核心蛋白质组数据集,并使用细菌全基因组分析(BPGA)进行细菌全基因组研究,以预测核心蛋白质序列,然后用于寻找良好的候选疫苗靶点。这确定了两种蛋白质,Hcp家族VI型分泌系统效应子和超氧化物歧化酶家族蛋白质,作为有前景的疫苗靶点。然后使用IEDB数据库,预测不同的B细胞和T细胞表位。选择了一组四个表位“KGSVNVQDRE、NTGKLTGTR、IIHSDSWNER和KDGKPVPALK”用于开发多表位疫苗构建体。一个183个氨基酸的长疫苗设计与“EAAAK”和“GPGPG”连接体以及霍乱毒素B亚单位佐剂一起构建。设计的疫苗模型包括免疫显性、无毒、非致敏和物理化学稳定的表位。使用Cluspro2.0网络服务器将模型疫苗与MHC-I、MHC-II和TLR-4免疫细胞受体对接。疫苗的结合能得分为- MHC-I为654.7kcal/mol- MHC-II为738.4 kcal/mol,以及- TLR-4为695.0 kcal/mol。使用AMBER v20软件包对纳秒内的动态行为进行了分子动力学模拟。此外,还进行了MM-PBSA结合自由能分析,以测试对接分子之间的分子间结合相互作用。MM-GBSA净结合能得分为- 148.00千卡/摩尔- 118.00 kcal/mol,以及- 使用TLR-4、MHC-I和MHC-II的疫苗分别为127.00 kcal/mol。总的来说,这些基于计算机的预测表明,该疫苗在开发对P.penneri的保护性免疫力方面非常有希望。然而,还需要额外的实验验证来揭示对设计疫苗的真正免疫反应。
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来源期刊
Molecular Biotechnology
Molecular Biotechnology 医学-生化与分子生物学
CiteScore
4.10
自引率
3.80%
发文量
165
审稿时长
6 months
期刊介绍: Molecular Biotechnology publishes original research papers on the application of molecular biology to both basic and applied research in the field of biotechnology. Particular areas of interest include the following: stability and expression of cloned gene products, cell transformation, gene cloning systems and the production of recombinant proteins, protein purification and analysis, transgenic species, developmental biology, mutation analysis, the applications of DNA fingerprinting, RNA interference, and PCR technology, microarray technology, proteomics, mass spectrometry, bioinformatics, plant molecular biology, microbial genetics, gene probes and the diagnosis of disease, pharmaceutical and health care products, therapeutic agents, vaccines, gene targeting, gene therapy, stem cell technology and tissue engineering, antisense technology, protein engineering and enzyme technology, monoclonal antibodies, glycobiology and glycomics, and agricultural biotechnology.
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