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Tensor-DTI: Enhancing Biomolecular Interaction Prediction with Contrastive Embedding Learning

Machine Learning 2026-01-12 v1 Artificial Intelligence Biomolecules

Abstract

Accurate drug-target interaction (DTI) prediction is essential for computational drug discovery, yet existing models often rely on single-modality predefined molecular descriptors or sequence-based embeddings with limited representativeness. We propose Tensor-DTI, a contrastive learning framework that integrates multimodal embeddings from molecular graphs, protein language models, and binding-site predictions to improve interaction modeling. Tensor-DTI employs a siamese dual-encoder architecture, enabling it to capture both chemical and structural interaction features while distinguishing interacting from non-interacting pairs. Evaluations on multiple DTI benchmarks demonstrate that Tensor-DTI outperforms existing sequence-based and graph-based models. We also conduct large-scale inference experiments on CDK2 across billion-scale chemical libraries, where Tensor-DTI produces chemically plausible hit distributions even when CDK2 is withheld from training. In enrichment studies against Glide docking and Boltz-2 co-folder, Tensor-DTI remains competitive on CDK2 and improves the screening budget required to recover moderate fractions of high-affinity ligands on out-of-family targets under strict family-holdout splits. Additionally, we explore its applicability to protein-RNA and peptide-protein interactions. Our findings highlight the benefits of integrating multimodal information with contrastive objectives to enhance interaction-prediction accuracy and to provide more interpretable and reliability-aware models for virtual screening.

Keywords

Cite

@article{arxiv.2601.05792,
  title  = {Tensor-DTI: Enhancing Biomolecular Interaction Prediction with Contrastive Embedding Learning},
  author = {Manel Gil-Sorribes and Júlia Vilalta-Mor and Isaac Filella-Mercè and Robert Soliva and Álvaro Ciudad and Víctor Guallar and Alexis Molina},
  journal= {arXiv preprint arXiv:2601.05792},
  year   = {2026}
}

Comments

Accepted at the Generative and Experimental Perspectives for Biomolecular Design Workshop at ICLR 2025 and at the Learning Meaningful Representations of Life Workshop at ICLR 2025

R2 v1 2026-07-01T08:57:45.218Z