AI Article Synopsis
- Identifying drug-target interactions (DTIs) is crucial for drug development, but current deep learning methods often struggle with redundancy and complicate the actual binding processes between drugs and targets.
- The proposed ReduMixDTI model enhances DTI prediction by using advanced graph and convolutional neural networks to improve feature representation and an attention mechanism to better capture complex interactions.
- Comparisons with other leading methods show that ReduMixDTI outperforms them on multiple benchmark data sets while providing improved interpretability through visualization of protein interactions.
Article Abstract
Identifying drug-target interactions (DTIs) is essential for drug discovery and development. Existing deep learning approaches to DTI prediction often employ powerful feature encoders to represent drugs and targets holistically, which usually cause significant redundancy and noise by neglecting the restricted binding regions. Furthermore, many previous DTI networks ignore or simplify the complex intermolecular interaction process involving diverse binding types, which significantly limits both predictive ability and interpretability. We propose ReduMixDTI, an end-to-end model that addresses feature redundancy and explicitly captures complex local interactions for DTI prediction. In this study, drug and target features are encoded by using graph neural networks and convolutional neural networks, respectively. These features are refined from channel and spatial perspectives to enhance the representations. The proposed attention mechanism explicitly models pairwise interactions between drug and target substructures, improving the model's understanding of binding processes. In extensive comparisons with seven state-of-the-art methods, ReduMixDTI demonstrates superior performance across three benchmark data sets and external test sets reflecting real-world scenarios. Additionally, we perform comprehensive ablation studies and visualize protein attention weights to enhance the interpretability. The results confirm that ReduMixDTI serves as a robust and interpretable model for reducing feature redundancy, contributing to advances in DTI prediction.
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| http://dx.doi.org/10.1021/acs.jcim.4c01554 | DOI Listing |
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