Frontiers in Immunology (Jan 2018)

A Recurrent Mutation in Anaplastic Lymphoma Kinase with Distinct Neoepitope Conformations

  • Jugmohit S. Toor,
  • Arjun A. Rao,
  • Andrew C. McShan,
  • Mark Yarmarkovich,
  • Santrupti Nerli,
  • Santrupti Nerli,
  • Karissa Yamaguchi,
  • Ada A. Madejska,
  • Son Nguyen,
  • Sarvind Tripathi,
  • John M. Maris,
  • Sofie R. Salama,
  • Sofie R. Salama,
  • David Haussler,
  • David Haussler,
  • Nikolaos G. Sgourakis

DOI
https://doi.org/10.3389/fimmu.2018.00099
Journal volume & issue
Vol. 9

Abstract

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The identification of recurrent human leukocyte antigen (HLA) neoepitopes driving T cell responses against tumors poses a significant bottleneck in the development of approaches for precision cancer therapeutics. Here, we employ a bioinformatics method, Prediction of T Cell Epitopes for Cancer Therapy, to analyze sequencing data from neuroblastoma patients and identify a recurrent anaplastic lymphoma kinase mutation (ALK R1275Q) that leads to two high affinity neoepitopes when expressed in complex with common HLA alleles. Analysis of the X-ray structures of the two peptides bound to HLA-B*15:01 reveals drastically different conformations with measurable changes in the stability of the protein complexes, while the self-epitope is excluded from binding due to steric hindrance in the MHC groove. To evaluate the range of HLA alleles that could display the ALK neoepitopes, we used structure-based Rosetta comparative modeling calculations, which accurately predict several additional high affinity interactions and compare our results with commonly used prediction tools. Subsequent determination of the X-ray structure of an HLA-A*01:01 bound neoepitope validates atomic features seen in our Rosetta models with respect to key residues relevant for MHC stability and T cell receptor recognition. Finally, MHC tetramer staining of peripheral blood mononuclear cells from HLA-matched donors shows that the two neoepitopes are recognized by CD8+ T cells. This work provides a rational approach toward high-throughput identification and further optimization of putative neoantigen/HLA targets with desired recognition features for cancer immunotherapy.

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