Litcius/Paper detail

Self-iterative multiple-instance learning enables the prediction of CD4+ T cell immunogenic epitopes

Long-Chen Shen, Yumeng Zhang, Zhikang Wang, Dene R. Littler, Yan Liu, Jinhui Tang, Jamie Rossjohn, Dong‐Jun Yu, Jiangning Song

2025Nature Machine Intelligence8 citationsDOIOpen Access PDF

Abstract

Abstract Accurate prediction of antigen presentation to CD4 + T cells and subsequent induction of immune response are fundamentally important for vaccine development, autoimmune disease treatment and cancer neoepitope discovery. In immunopeptidomics, single-allelic data offer high specificity but limited allele coverage, whereas multi-allelic data provide broader representation at the expense of weak labelling. Current computational approaches either overlook the abundance of multi-allelic data or suffer from label ambiguity due to inadequate modelling strategies. To address these limitations, we present ImmuScope, a weakly supervised deep learning framework that integrates major histocompatibility complex class II (MHC-II) antigen presentation, CD4 + T cell epitopes and immunogenicity assessment. ImmuScope leverages self-iterative multiple-instance learning with positive-anchor triplet loss to decipher peptide-MHC-II binding from weakly labelled multi-allelic data and high-confidence single-allelic data. The training dataset comprises over 600,000 ligands across 142 alleles. Additionally, ImmuScope enables the interpretation of MHC-II binding specificity and motif deconvolution of immunopeptidomics data. We successfully applied ImmuScope to identify melanoma neoantigens, uncovering mutation-driven variations in peptide-MHC-II binding and immunogenicity. Furthermore, we employed ImmuScope to evaluate the effects of SARS-CoV-2 epitope mutations associated with immune escape, with predictions well aligned with experimentally observed immune escape dynamics. Overall, by offering a unified solution for CD4 + T cell antigen recognition and immunogenicity assessment, ImmuScope holds substantial promise for accelerating vaccine design and advancing personalized immunotherapy.

Topics & Concepts

EpitopeComputer scienceComputational biologyT cellVirologyImmunologyBiologyAntigenImmune systemvaccines and immunoinformatics approachesImmunotherapy and Immune ResponsesT-cell and B-cell Immunology