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MATE-Pred: Multimodal Attention-based TCR-Epitope interaction Predictor

Machine Learning 2024-01-18 v1 Artificial Intelligence

Abstract

An accurate binding affinity prediction between T-cell receptors and epitopes contributes decisively to develop successful immunotherapy strategies. Some state-of-the-art computational methods implement deep learning techniques by integrating evolutionary features to convert the amino acid residues of cell receptors and epitope sequences into numerical values, while some other methods employ pre-trained language models to summarize the embedding vectors at the amino acid residue level to obtain sequence-wise representations. Here, we propose a highly reliable novel method, MATE-Pred, that performs multi-modal attention-based prediction of T-cell receptors and epitopes binding affinity. The MATE-Pred is compared and benchmarked with other deep learning models that leverage multi-modal representations of T-cell receptors and epitopes. In the proposed method, the textual representation of proteins is embedded with a pre-trained bi-directional encoder model and combined with two additional modalities: a) a comprehensive set of selected physicochemical properties; b) predicted contact maps that estimate the 3D distances between amino acid residues in the sequences. The MATE-Pred demonstrates the potential of multi-modal model in achieving state-of-the-art performance (+8.4\% MCC, +5.5\% AUC compared to baselines) and efficiently capturing contextual, physicochemical, and structural information from amino acid residues. The performance of MATE-Pred projects its potential application in various drug discovery regimes.

Keywords

Cite

@article{arxiv.2401.08619,
  title  = {MATE-Pred: Multimodal Attention-based TCR-Epitope interaction Predictor},
  author = {Etienne Goffinet and Raghvendra Mall and Ankita Singh and Rahul Kaushik and Filippo Castiglione},
  journal= {arXiv preprint arXiv:2401.08619},
  year   = {2024}
}

Comments

Patent pending: U.S. Provisional Application No. 63/603,952

R2 v1 2026-06-28T14:18:24.925Z