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Virology & Immunology Journal Research Article 9 min read

Immunoinformatic Approaches in Epitope Prediction for Vaccine Designing against Viral infections

Raghuwanshi R*, Singh M and Shukla V
* Corresponding author
ISSN: 2577-4379  10.23880/vij-16000142  Received: January 25, 2018  Published: February 03, 2018
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Keywords
Epitope Vaccine Design Viral Infections
Abstract

Epitope prediction of immunogens using bioinformatic approaches is supposed to bring a revolution in vaccine development. Computer based prediction tools has reduced both the number of validation experiments and time for epitope prediction. A number of epitope prediction tools are now available on the web, and bioinformatics-based prediction of CTL epitopes has gained huge popularity in drug designing. For a vaccine to be successful against the viral infections, it needs to ideally stimulate humoral or cellular immune responses. The in silico search mainly focuses for individual immunogenic components that can target different arms of the immune system. Peptide based drug can be designed by targeting the protein, involved in stimulating the host cell immune system. Perspectives in this field are presented in the present review.

Introduction

Effective method for prevention of viral infections has been vaccination. Conventional methods to design vaccine candidate is a laborious process requiring time and economy. During the last three decades efforts to control of viral diseases through the development of large number of antiretroviral drugs, public awareness and other prevention programs across the globe has led to significant reduction in viral cases yet, constantly evolving and drug resistant mutations are posing a continuous challenge to the therapy. This beckons an urgent need for effective vaccines offering a stable solution to control and eradicate the disease. Epitope based vaccine designing is more promising as the conventional approach lies on the responses induced by the natural immunogen which are not optimal. Epitope based drug designing relies not only on understanding the mechanisms of immunodominance but simultaneously analyzes multiple genomes to select the most appropriate epitope.

Challenges in Conventional Methods of Vaccine Development

Development of vaccines or therapeutic measures often requires prior understanding of the immunological aspects during the natural course of an infection. Conventional vaccines prepared by either attenuated or inactivated whole pathogen has a number of limitations as genetic variations in these pathogens all over the globe may results in reduced efficiency of these vaccines in different parts of the world. Many vaccine trials are currently being conducted worldwide, but they fail to reach in phase III. These facts indicate clearly that there is a big gap between the early phase clinical trials (phase I and II) and efficacy trial (phase III) and the need for further research to gain more knowledge on minimal components which determine the protective nature of the vaccine candidates against virus is desired [1]. Genetic variation in envelope proteins is one of the main hurdles in designing a vaccine [2]. Experimental assays for identification of conserved regions which maintain their structure and function of glycoprotein is a tedious process. Besides this the pathogens utilized during vaccination may revert to its pathogenic form and cause infection [3].

Vaccine Designing through Immunoinformatics

Immunoinformatics, an emerging field of the present era has addressed the complex biological problem of decrypting the immune response for vaccine designing [4]. An ideal vaccine which initiates humoral or cell mediated immune response is essential to completely eradicate the chance of re-infection. The Cytotoxic T lymphocytes (CTL) and Helper T lymphocytes (HTL) recognizes the foreign antigen as peptides that are presented with Major Histocompatibility Complex (MHC) and is expressed on the surface of all nucleated cells. T cell epitope prediction tools assist in identifying allele- specific peptides, thus reducing the number of potential peptides to be considered as vaccine candidates. A rationally designed epitope based vaccine lies in understanding of antigen recognition by both T and B lymphocytes [5, 6]. Conserved regions which maintain its structure and function of envelope glycoprotein are searched. The surface of the mature virus which has a large number of envelope proteins can be one of the initiating points for the systematic search of cavities in order to encounter those compounds which are able to interfere with the protein rearrangements. Besides this the protein responsible for participation in cell recognition, cell entrance are also targeted. In silico epitope predictions tools have proved advantageous in determining the potential candidates reducing the number of validation experiments and time [7, 8]. Presently, huge numbers of computational tools are available to predict peptides (T and B cell) with necessary properties [8]. Algorithms based on binding motifs, Position Specific Scoring Matrices (PSSM), Artificial Neural Network (ANN) and Support Vector Machine (SVM) are often used to predict potential MHC binders.

ProtParam and SOPMA (self optimized prediction method with alignment) of Expasy server can be used for predicting epitope’s physiological and chemical characteristics. ProtParam tool show the isoelectric point (pI), molecular weight, amino acid composition, grand average hydropathicity (GRAVY), estimated half-life, extinction coefficient, instability index and aliphatic index of predicted protein sequence [3, 15, 16, 17]. Grand average hydropathicity (GRAVY) value of protein sequence shows it’s hydrophilic and hydrophobic nature i.e, higher the negative value higher will be its hydrophilicity. Computational approaches for the prediction of highly immunogenic epitope has been employed for a number of viruses as listed in Table 1.

Bioinformatic Tools for T cell Epitope Prediction

Cytotoxic and helper T-cell epitopes are MHC bound sequences and attach in linear form. Epitopes are linked to MHC class I and MHC class II through their side chain interactions. Based on this, various tools predicting MHC class I binding Cytotoxic T-cell epitopes are designed like ProPred1, NetCTLpan, nHLAPed, RANKPEP, CTLPred, NetTepi. Tools for Helper T-cell recognizing epitopes bound to MHC class II are Propred, EpiDOCK, EpiTOP, MHC2Pred, HLA-DR4Pred [9]. MHC-II binding epitopes have proven less accurate compared to MHC-I [10].

Bioinformatic Tools for B Cell Epitope Prediction

Identification of B-cell epitopes (antigenic regions that stimulate B cell response) is a prominently forward step to propose a peptide vaccine. B-cell epitopes can be both of continuous or discontinuous type. Continuous B-cell epitope prediction is mainly based on the amino acid properties such as hydrophilicity, charge, exposed surface area and secondary structure. Discontinuous B cell epitope prediction requires 3D structure of the antigen [11, 12, 13, 14]. Various tools have been developed using different algorithms for B-cell epitope prediction. ABCpred, bepiPred, LBtope, APCpred tools are used to predict continuous B cell epitopes. Disco Tope 2.0 server, BEPro (PEPITO), SEPPA helps in prediction of discontinuous epitopes. Epitopia, ElliPro, PepSurf servers help in predicting both continuous and discontinuous epitopes. For continuous epitope driven vaccine design tools like ABCpred, bepiPred, LBtope and APCpred are available.

Physicochemical Characterization of Epitopes

S. No.VirusTargeted ProteinAntigensReferences
1.Avian leukosis
virus subgroup J		Surface glycoprotein
Gp85Wang et al. (2017) [18]
2.Rabies virusGlycoprotein with
molecular adjuvant used
C3d-P28.
Galvez-Romero et al. (2018)
G5
[19]
3.HantavirusSurface glycoproteinpVAX-LAMP/GcJiang et al. (2017) [20]
4.Human immunodeficieny
virus		Envelope glycoprotein
Gp120Thomas et al. (2014) [21]
5.Aleutian mink disease
virus		Capsid protein
VP2Lu et al. (2017) [22]
6.Avian leukosis
Virus		Structural protein
P27Khairy et al. (2017) [23]
7.Influenza A and B virus.Surface glycoproteinHaemagglutininRen H and Zhou P. (2016) [24]
8.CoronavirusSpike protein and
membrane protein
S and M proteinWang et al. (2008) [25]
9.Influenza A virus
subtype H9N2		Matrix protein and
surface glycoprotein
M2e-HA2Golchin et al. (2017) [26]
10.Zika virusEnvelop protein5IREDey et al. (2017) [27]
11.Varicella-zoster
Virus		Envelop glycoprotein
gE proteinZhu et al. (2016) [28]
12.Infectious brusal disease
virus (IBDV) and
Newcastle disease virus
(NDV)		Capsid protein and
integral membrane
protein (45)
VP2 protein and HN
Liu et al. (2015) [29]
protein
13.Rift valley fever virusNucleocapsid and
Glycoprotein		Adhikari and Rahman (2017)
N and G protein
[30]
14.Human bocavirus 1Capsid proteinVp2Kalyanaraman N (2018) [31]
15.Ebola virusCoat proteinsGP2 and VP24Srivastava et al. (2016) [32]
16.Zika virusStructural and non
structural protein.		Capsid 1 protein,
membrane protein, E
Dikhit et al. (2016) [33]
protein, NS1, NS2A, NS2B,
NS3, NS4A, NS4B, NS5
17.Influenza A virus(H1
subtype)		Surface glycoprotein
HAGuo et al. (2015) [34]
18.Chikungunya virusNon structural
polyprotein
nsPPPratheek et al. (2015) [35]

Table 1: Reports on epitope based peptide vaccine design.

Conclusion

Epitope driven vaccine designing has come as an attractive concept in both clinical and biomedical research and holds huge potential to replace the attenuated pathogen based vaccination. Improvements in in silico analysis and experimental evaluation will be critical in finally making it a success. Conflict of Interest Statement: The authors declare that there is no conflict of interest regarding this study.

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@article{raghuwanshi2018,
  title   = {Immunoinformatic Approaches in Epitope Prediction for Vaccine Designing against Viral infections},
  author  = {Raghuwanshi R, Singh M and Shukla V},
  journal = {Virology & Immunology Journal},
  year    = {2018},
  volume  = {2},
  number  = {2},
  doi     = {10.23880/vij-16000142}
}
Raghuwanshi R, Singh M and Shukla V (2018). Immunoinformatic Approaches in Epitope Prediction for Vaccine Designing against Viral infections. Virology & Immunology Journal, 2(2). https://doi.org/10.23880/vij-16000142
TY  - JOUR
TI  - Immunoinformatic Approaches in Epitope Prediction for Vaccine Designing against Viral infections
AU  - Raghuwanshi R, Singh M and Shukla V
JO  - Virology & Immunology Journal
PY  - 2018
VL  - 2
IS  - 2
DO  - 10.23880/vij-16000142
ER  -