PLoS ONE (Jan 2016)

Determination of B-Cell Epitopes in Patients with Celiac Disease: Peptide Microarrays.

  • Rok Seon Choung,
  • Eric V Marietta,
  • Carol T Van Dyke,
  • Tricia L Brantner,
  • John Rajasekaran,
  • Pankaj J Pasricha,
  • Tianhao Wang,
  • Kang Bei,
  • Karthik Krishna,
  • Hari K Krishnamurthy,
  • Melissa R Snyder,
  • Vasanth Jayaraman,
  • Joseph A Murray

DOI
https://doi.org/10.1371/journal.pone.0147777
Journal volume & issue
Vol. 11, no. 1
p. e0147777

Abstract

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BACKGROUND:Most antibodies recognize conformational or discontinuous epitopes that have a specific 3-dimensional shape; however, determination of discontinuous B-cell epitopes is a major challenge in bioscience. Moreover, the current methods for identifying peptide epitopes often involve laborious, high-cost peptide screening programs. Here, we present a novel microarray method for identifying discontinuous B-cell epitopes in celiac disease (CD) by using a silicon-based peptide array and computational methods. METHODS:Using a novel silicon-based microarray platform with a multi-pillar chip, overlapping 12-mer peptide sequences of all native and deamidated gliadins, which are known to trigger CD, were synthesized in situ and used to identify peptide epitopes. RESULTS:Using a computational algorithm that considered disease specificity of peptide sequences, 2 distinct epitope sets were identified. Further, by combining the most discriminative 3-mer gliadin sequences with randomly interpolated3- or 6-mer peptide sequences, novel discontinuous epitopes were identified and further optimized to maximize disease discrimination. The final discontinuous epitope sets were tested in a confirmatory cohort of CD patients and controls, yielding 99% sensitivity and 100% specificity. CONCLUSIONS:These novel sets of epitopes derived from gliadin have a high degree of accuracy in differentiating CD from controls, compared with standard serologic tests. The method of ultra-high-density peptide microarray described here would be broadly useful to develop high-fidelity diagnostic tests and explore pathogenesis.