BindingSiteDTI: differential-scale binding site modelling for drug–target interaction prediction

Abstract Motivation Enhanced by contemporary computational advances, the prediction of drug–target interactions (DTIs) has become crucial in developing de novo and effective drugs. Existing deep learning approaches to DTI prediction are frequently beleaguered by a tendency to overfit specific molecu...

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Bibliographic Details
Published in:Bioinformatics (Oxford, England) England), 2024-05, Vol.40 (5)
Main Authors: Pan, Feng, Yin, Chong, Liu, Si-Qi, Huang, Tao, Bian, Zhaoxiang, Yuen, Pong Chi
Format: Article
Language:English
Subjects:
Benchmarks
Binding Sites
Computational Biology - methods
Deep Learning
Drug discovery
Drug Discovery - methods
Drug interaction
Drugs
Humans
Network reliability
Original Paper
Pharmaceutical Preparations - chemistry
Pharmaceutical Preparations - metabolism
Predictions
Source code
Citations: Items that this one cites
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Summary:Abstract Motivation Enhanced by contemporary computational advances, the prediction of drug–target interactions (DTIs) has become crucial in developing de novo and effective drugs. Existing deep learning approaches to DTI prediction are frequently beleaguered by a tendency to overfit specific molecular representations, which significantly impedes their predictive reliability and utility in novel drug discovery contexts. Furthermore, existing DTI networks often disregard the molecular size variance between macro molecules (targets) and micro molecules (drugs) by treating them at an equivalent scale that undermines the accurate elucidation of their interaction. Results We propose a novel DTI network with a differential-scale scheme to model the binding site for enhancing DTI prediction, which is named as BindingSiteDTI. It explicitly extracts multiscale substructures from targets with different scales of molecular size and fixed-scale substructures from drugs, facilitating the identification of structurally similar substructural tokens, and models the concealed relationships at the substructural level to construct interaction feature. Experiments conducted on popular benchmarks, including DUD-E, human, and BindingDB, shown that BindingSiteDTI contains significant improvements compared with recent DTI prediction methods. Availability and implementation The source code of BindingSiteDTI can be accessed at https://github.com/MagicPF/BindingSiteDTI.
ISSN:1367-4811
1367-4803
1367-4811
DOI:10.1093/bioinformatics/btae308