Abstract
Background and Objective: Vibrio cholerae continues to emerge as a dangerous pathogen because of increasing resistance to a number of antibiotics. This paper provides a solution to emerging antibiotic resistance by introducing novel proteins as vaccine candidates against cholera. Materials and Methods: Vibrio cholerae genome versatility is a hurdle for developing a vaccine to combat diarrhoeal infection, so its core gene information was used to determine a potential vaccine candidate. Whole genome sequence data of more than 100 Vibrio cholerae strains were used simultaneously to get core genome information. The VacSol pipeline based on reverse vaccinology was selected to address the problem of safe, cheap, temperature-stable, and effective vaccine candidates which can be used for vaccine development against Vibrio cholerae. VacSol screens vaccine candidates using integrated, well-known, and robust algorithms/tools for proteome analysis. The proteomes of the pathogens were initially screened to predict homology using BLASTp. Proteomes that are non-homologous to humans are then subjected to a predictor for localization. Helicer predicts transmembrane helices for the protein. Proteins failing to comply with the set parameters were filtered at each step, and finally, 11 proteins were filtered as vaccine candidates. Results: This selected group of vaccine candidates consists of proteins from almost all structural parts of Vibrio cholerae. Their blast results show that this filtered group includes flagellin A protein, a protein from the Zn transporter system, a lipocarrier outer membrane protein, a peptidoglycan-associated protein, a DNA-binding protein, a chemotaxis protein, a tRNA Pseuriudine synthase A, and two selected proteins, which were beta lactamases. The last two uncharacterized proteins possess 100% similarity to V. albensis and Enterobacter, respectively. Tertiary structure and active site determination show a large number of pockets on each protein. Conclusions: The most interesting finding of this study is that 10 proteins out of 11 filtered proteins are introduced as novel potential vaccine candidates. These novel vaccine candidates can result in the development of cost-effective and broad-spectrum vaccines which can be used in countries where cholera is a major contributor to diarrheal disease.
Highlights
Cholera is a fecal orally transmitted infection and caused by the Gram-negative toxigenic bacterium Vibrio cholerae
In silico vaccine candidate determination of Vibrio cholerae isolates was carried out first time and a newly designed more advanced software VacSol pipeline [24]
The results summary report has shown that pipeline has filtered 11 proteins from 998 core genes from a set of 100 genomic sequences of Vibrio cholerae which can be used as successful therapeutic agents
Summary
Cholera is a fecal orally transmitted infection and caused by the Gram-negative toxigenic bacterium Vibrio cholerae. Human is its only known vertebral host [1]. It is responsible for Cholera endemic in southern Asia since recorded history. Its colonization in intestine results in acute watery diarrhea which act as infectious entity helping in infection spreading and epidemics [2]. Vibrio cholerae serotype O1, causes majority of cholera outbreaks which is divided into classical (CL) and El Tor (ET) biotypes. Vibrio cholerae continues to emerge as a dangerous pathogen because of increasing resistance to a number of antibiotics. This paper provides a solution to emerging antibiotic resistance by introducing novel proteins as vaccine candidates against cholera
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