Exploring rotavirus proteome to identify potential B- and T-cell epitope using computational immunoinformatics

Yengkhom Damayanti Devi,Arpita Devi,Hemanga Gogoi,Bondita Dehingia,Robin Doley,Alak Kumar Buragohain,Ch Shyamsunder Singh,Partha Pratim Borah,C.Durga Rao,Pratima Ray,George M Varghese,Sachin Kumar,Nima D Namsa

doi:10.1016/j.heliyon.2020.e05760

Abstract

Rotavirus is the most common cause of acute gastroenteritis in infants and children worldwide. The functional correlation of B- and T-cells to long-lasting immunity against rotavirus infection in the literature is limited. In this work, a series of computational immuno-informatics approaches were applied and identified 28 linear B-cells, 26 conformational B-cell, 44 TC cell and 40 TH cell binding epitopes for structural and non-structural proteins of rotavirus. Further selection of putative B and T cell epitopes in the multi-epitope vaccine construct was carried out based on immunogenicity, conservancy, allergenicity and the helical content of predicted epitopes. An in-silico vaccine constructs was developed using an N-terminal adjuvant (RGD motif) followed by TC and TH cell epitopes and B-cell epitope with an appropriate linker. Multi-threading models of multi-epitope vaccine construct with B- and T-cell epitopes were generated and molecular dynamics simulation was performed to determine the stability of designed vaccine. Codon optimized multi-epitope vaccine antigens was expressed and affinity purified using the E. coli expression system. Further the T cell epitope presentation assay using the recombinant multi-epitope constructs and the T cell epitope predicted and identified in this study have not been investigated. Multi-epitope vaccine construct encompassing predicted B- and T-cell epitopes may help to generate long-term immune responses against rotavirus. The computational findings reported in this study may provide information in developing epitope-based vaccine and diagnostic assay for rotavirus-led diarrhea in children's.

Highlights

Rotavirus is the most common cause of acute gastroenteritis in infants and children worldwide
Genetic analysis of selected virus reassortants identified several proteins of rotaviruses but not limited to VP3, VP4, VP6, VP7, NSP1, NSP2, NSP3, and NSP4 that are involved in virulence
Rotavirus NSP4 was predicted as non-antigen by VaxiJen which might be due to the limitation of server

Summary

Introduction

Rotavirus is the most common cause of acute gastroenteritis in infants and children worldwide. As per WHO reports of 2013 about 215 000 children under five-years of age die annually due to rotavirus infections mainly in low-income countries [1]. Rotavirus particles naturally excreted in the stools of infected children are transmitted mainly through the fecal-oral route, close-contact and fomites [2]. The mature infectious rotavirus particles is made up of three layers of capsid proteins: outer (proteins VP7 and VP4), middle (protein VP6), and inner (protein VP2). The dsRNA genome of rotavirus encodes for 6 structural proteins and 6 non-structural proteins [3]. Rotavirus infectivity is enhanced by cleavage of VP4 protein into two fragments, VP5* (facilitates cell membrane penetration) and VP8* (mediates cell attachment) [4]. Rotavirus is further divided into nine serogroups (A-I) based on group specific viral antigen VP6 [6]

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Conclusion