Development of a multi-epitope antigen of S protein-based ELISA for antibodies detection against infectious bronchitis virus

An indirect enzyme-linked immunosorbent assay (ELISA) method based on a novel multi-epitope antigen of S protein (SE) was developed for antibodies detection against infectious bronchitis virus (IBV). The multi-epitope antigen SE protein was designed by arranging three S gene fragments (166–247 aa, S1 gene; 501–515 aa, S1 gene; 8–30 aa, S2 gene) in tandem. It was identified to be approximately 32 kDa as a His-tagged fusion protein and can bind IBV positive serum by western blot analysis. The conditions of the SE-ELISA method were optimized. The optimal concentration of the coating antigen SE was 3.689 μg/mL and the dilution of the primary antibodies was identified as 1:1000 using a checkerboard titration. The cut-off OD450 value was established at 0.332. The relative sensitivity and specificity between the SE-ELISA and IDEXX ELISA kit were 92.38 and 89.83%, respectively, with an accuracy of 91.46%. This assay is sensitive and specific for detection of antibodies against IBV. Schematic representation of the multi-epitope antigen (SE). The black blocks represent the gene fragments. The blank blocks represent the flexible amino acids.

[1]  U. Liebert,et al.  Development of a recombinant ELISA using yeast (Pichia pastoris)-expressed polypeptides for detection of antibodies against avian influenza A subtype H5. , 2012, Journal of virological methods.

[2]  N. Nagelkerke,et al.  Evaluation of a multi-antigen test based on B-cell epitope peptides for the serodiagnosis of pulmonary tuberculosis. , 2009, The international journal of tuberculosis and lung disease : the official journal of the International Union against Tuberculosis and Lung Disease.

[3]  A. S. Abdel-Moneim,et al.  High-level protein expression following single and dual gene cloning of infectious bronchitis virus N and S genes using baculovirus systems. , 2014, Viral immunology.

[4]  E. Collisson,et al.  A highly conserved epitope on the spike protein of infectious bronchitis virus , 2005, Archives of Virology.

[5]  J. Lenstra,et al.  Antigenicity of the peplomer protein of infectious bronchitis virus , 1989, Molecular Immunology.

[6]  F. Osorio,et al.  Recombinant viral proteins for use in diagnostic ELISAs to detect virus infection , 2007, Vaccine.

[7]  D. Cavanagh,et al.  Coronavirus IBV: removal of spike glycopolypeptide S1 by urea abolishes infectivity and haemagglutination but not attachment to cells. , 1986, The Journal of general virology.

[8]  N. Chandra,et al.  Computational analysis of proteome of H5N1 avian influenza virus to define T cell epitopes with vaccine potential. , 2007, Vaccine.

[9]  J. Lenstra,et al.  Analysis of an immunodominant region of infectious bronchitis virus. , 1989, Journal of immunology.

[10]  D. Cavanagh,et al.  Relationship between sequence variation in the S1 spike protein of infectious bronchitis virus and the extent of cross-protection in vivo. , 1997, Avian pathology : journal of the W.V.P.A.

[11]  J. Ignjatovic,et al.  Identification of previously unknown antigenic epitopes on the S and N proteins of avian infectious bronchitis virus , 2005, Archives of Virology.

[12]  P. E. Givisiez,et al.  Development and Application of a Saccharomyces cerevisiae-Expressed Nucleocapsid Protein-Based Enzyme-Linked Immunosorbent Assay for Detection of Antibodies against Infectious Bronchitis Virus , 2005, Journal of Clinical Microbiology.

[13]  Santiago Garcia-Vallvé,et al.  Working toward a new NIOSH. , 1996, Nucleic Acids Res..

[14]  V. Drygin,et al.  Detection of antibodies to avian infectious bronchitis virus by a recombinant nucleocapsid protein-based enzyme-linked immunosorbent assay , 2006, Journal of Virological Methods.

[15]  D. Cavanagh,et al.  Location of the amino acid differences in the S1 spike glycoprotein subunit of closely related serotypes of infectious bronchitis virus. , 1992, Avian pathology : journal of the W.V.P.A.

[16]  I. Haro,et al.  Assessment of synthetic chimeric multiple antigenic peptides for diagnosis of GB virus C infection. , 2010, Analytical biochemistry.

[17]  F. J. Poelwijk,et al.  Location of antigenic sites defined by neutralizing monoclonal antibodies on the S1 avian infectious bronchitis virus glycopolypeptide. , 1992, The Journal of general virology.

[18]  Joo Chuan Tong,et al.  SVM-based prediction of linear B-cell epitopes using Bayes Feature Extraction , 2010, BMC Genomics.

[19]  Xiao-yan Feng,et al.  Double-antigen sandwich ELISA for the detection of anti-hepatitis C virus antibodies. , 2011, Journal of virological methods.

[20]  Morten Nielsen,et al.  Improved method for predicting linear B-cell epitopes , 2006, Immunome research.

[21]  S. Reed,et al.  A multi-epitope synthetic peptide and recombinant protein for the detection of antibodies to Trypanosoma cruzi in radioimmunoprecipitation-confirmed and consensus-positive sera. , 1999, The Journal of infectious diseases.

[22]  A. Jana,et al.  Recombinant Multiepitope Protein for Early Detection of Dengue Infections , 2006, Clinical and Vaccine Immunology.

[23]  J. Kataria,et al.  Recombinant nucleocapsid protein based single serum dilution ELISA for the detection of antibodies to infectious bronchitis virus in poultry. , 2014, Journal of virological methods.

[24]  C.-H. Wang,et al.  An ELISA for antibodies against infectious bronchitis virus using an S1 spike polypeptide. , 2002, Veterinary microbiology.

[25]  E. Ebrahimie,et al.  Multimeric Recombinant M2e Protein-Based ELISA: A Significant Improvement in Differentiating Avian Influenza Infected Chickens from Vaccinated Ones , 2014, PloS one.

[26]  Harinder Singh,et al.  Improved Method for Linear B-Cell Epitope Prediction Using Antigen’s Primary Sequence , 2013, PloS one.

[27]  J. Kataria,et al.  Recombinant haemagglutinin neuraminidase antigen-based single serum dilution ELISA for rapid serological profiling of Newcastle disease virus. , 2006, Journal of virological methods.

[28]  W. Hsu,et al.  Application of purified recombinant antigenic spike fragments to the diagnosis of avian infectious bronchitis virus infection , 2012, Applied Microbiology and Biotechnology.

[29]  Santiago Garcia-Vallvé,et al.  HEG-DB: a database of predicted highly expressed genes in prokaryotic complete genomes under translational selection , 2007, Nucleic Acids Res..

[30]  Sudipto Saha,et al.  Prediction of continuous B‐cell epitopes in an antigen using recurrent neural network , 2006, Proteins.

[31]  J. Hiscox,et al.  Evaluation of a nucleoprotein-based enzyme-linked immunosorbent assay for the detection of antibodies against infectious bronchitis virus , 2003, Avian Pathology.

[32]  Li Dandan,et al.  Design and evaluation of a recombinant multi-epitope-based ELISA for the serological surveillance of HEV infection in northern China , 2011, Archives of Virology.

[33]  V. V. Khrustalev Mutational pressure makes HIV1 gp120 linear B-cell epitopes shorter and may lead to their disappearance. , 2010, Molecular immunology.

[34]  O. Taboga,et al.  Multiple recombinant ELISA for the detection of bovine viral diarrhoea virus antibodies in cattle sera. , 2006, Journal of virological methods.