IMPROVE: a feature model to predict neoepitope immunogenicity through broad-scale validation of T-cell recognition

Annie Borch; Ibel Carri; Birkir Reynisson; Heli M. Garcia Alvarez; Kamilla Kjærgaard Munk; Alessandro Montemurro; Nikolaj Pagh Kristensen; Siri Tvingsholm; Jeppe Sejerø Holm; Christina Heeke; Keith Moss; Ulla Kring Hansen; Anna‐Lisa Schaap‐Johansen; Frederik Otzen Bagger; Vinicius Araújo Barbosa de Lima; Kristoffer Staal Rohrberg; Samuel A. Funt; Marco Donia; Inge Marie Svane; Ulrik Lassen; Carolina Barra; Morten Nielsen; Sine Reker Hadrup

doi:10.3389/fimmu.2024.1360281

IMPROVE: a feature model to predict neoepitope immunogenicity through broad-scale validation of T-cell recognition

Annie Borch(Technical University of Denmark), Ibel Carri(National University of General San Martín), Birkir Reynisson(Technical University of Denmark), Heli M. Garcia Alvarez(National University of General San Martín), Kamilla Kjærgaard Munk(Technical University of Denmark), Alessandro Montemurro(Technical University of Denmark), Nikolaj Pagh Kristensen(Technical University of Denmark), Siri Tvingsholm(Technical University of Denmark), Jeppe Sejerø Holm(Technical University of Denmark), Christina Heeke(Technical University of Denmark), Keith Moss(Technical University of Denmark), Ulla Kring Hansen(Technical University of Denmark), Anna‐Lisa Schaap‐Johansen(Technical University of Denmark), Frederik Otzen Bagger(Copenhagen University Hospital), Vinicius Araújo Barbosa de Lima(Rigshospitalet), Kristoffer Staal Rohrberg(Rigshospitalet), Samuel A. Funt(Cornell University), Marco Donia(Copenhagen University Hospital), Inge Marie Svane(Copenhagen University Hospital), Ulrik Lassen(Rigshospitalet), Carolina Barra(Technical University of Denmark), Morten Nielsen(National University of General San Martín), Sine Reker Hadrup(Technical University of Denmark)

Frontiers in Immunology

April 3, 2024

10.3389/fimmu.2024.1360281

Cited by 26Open Access

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Abstract

Background: Mutation-derived neoantigens are critical targets for tumor rejection in cancer immunotherapy, and better tools for neoepitope identification and prediction are needed to improve neoepitope targeting strategies. Computational tools have enabled the identification of patient-specific neoantigen candidates from sequencing data, but limited data availability has hindered their capacity to predict which of the many neoepitopes will most likely give rise to T cell recognition. Method: To address this, we make use of experimentally validated T cell recognition towards 17,500 neoepitope candidates, with 467 being T cell recognized, across 70 cancer patients undergoing immunotherapy. Results: We evaluated 27 neoepitope characteristics, and created a random forest model, IMPROVE, to predict neoepitope immunogenicity. The presence of hydrophobic and aromatic residues in the peptide binding core were the most important features for predicting neoepitope immunogenicity. Conclusion: Overall, IMPROVE was found to significantly advance the identification of neoepitopes compared to other current methods.

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