DeepCompoundNet: enhancing compound-protein interaction prediction with multimodal convolutional neural networks.

Virtual screening has emerged as a valuable computational tool for predicting compound-protein interactions, offering a cost-effective and rapid approach to identifying potential candidate drug molecules. Current machine learning-based methods rely on molecular structures and their relationship in the network. The former utilizes information such as amino acid sequences and chemical structures, while the latter leverages interaction network data, such as protein-protein interactions, drug-disease interactions, and protein-disease interactions. However, there has been limited exploration of integrating molecular information with interaction networks. This study presents DeepCompoundNet, a deep learning-based model that integrates protein features, drug properties, and diverse interaction data to predict chemical-protein interactions. DeepCompoundNet outperforms state-of-the-art methods for compound-protein interaction prediction, as demonstrated through performance evaluations. Our findings highlight the complementary nature of multiple interaction data, extending beyond amino acid sequence homology and chemical structure similarity. Moreover, our model's analysis confirms that DeepCompoundNet gets higher performance in predicting interactions between proteins and chemicals not observed in the training samples.Communicated by Ramaswamy H. Sarma.

[1]  S. Gharaghani,et al.  TripletMultiDTI: Multimodal representation learning in drug-target interaction prediction with triplet loss function , 2023, Expert Syst. Appl..

[2]  Jahan B. Ghasemi,et al.  DeepTraSynergy: drug combinations using multimodal deep learning with transformers , 2023, Bioinform..

[3]  Haitao Gan,et al.  Mutual-DTI: A mutual interaction feature-based neural network for drug-target protein interaction prediction. , 2023, Mathematical biosciences and engineering : MBE.

[4]  Qiujie Lv,et al.  Geometric Interaction Graph Neural Network for Predicting Protein-Ligand Binding Affinities from 3D Structures (GIGN). , 2023, The journal of physical chemistry letters.

[5]  Zhuhong You,et al.  DeepMPF: deep learning framework for predicting drug–target interactions based on multi-modal representation with meta-path semantic analysis , 2023, Journal of Translational Medicine.

[6]  Yi Yue,et al.  A deep learning framework for identifying essential proteins based on multiple biological information , 2022, BMC Bioinformatics.

[7]  Zi Liu,et al.  cpxDeepMSA: A Deep Cascade Algorithm for Constructing Multiple Sequence Alignments of Protein–Protein Interactions , 2022, International journal of molecular sciences.

[8]  M. Mukherjee,et al.  Systematic comparison of the protein-protein interaction network of bacterial Universal stress protein A (UspA): an insight into its discrete functions , 2022, Biologia.

[9]  Lyu Zhijian,et al.  GDGRU-DTA: Predicting Drug-Target Binding Affinity Based on GNN and Double GRU , 2022, Data Mining and Machine Learning.

[10]  J. Bajorath,et al.  Evolution of Support Vector Machine and Regression Modeling in Chemoinformatics and Drug Discovery , 2022, Journal of Computer-Aided Molecular Design.

[11]  Junzhou Huang,et al.  Application advances of deep learning methods for de novo drug design and molecular dynamics simulation , 2021, WIREs Computational Molecular Science.

[12]  K. Roszkowski,et al.  Machine learning in drug design: Use of artificial intelligence to explore the chemical structure–biological activity relationship , 2021, WIREs Computational Molecular Science.

[13]  Fiona L. Kearns,et al.  CIFDock: A novel CHARMM‐based flexible receptor–flexible ligand docking protocol , 2021, J. Comput. Chem..

[14]  Mohammad Ali Zare Chahooki,et al.  AutoDTI++: deep unsupervised learning for DTI prediction by autoencoders , 2021, BMC Bioinformatics.

[15]  Sun Kim,et al.  A review on compound-protein interaction prediction methods: Data, format, representation and model , 2021, Computational and structural biotechnology journal.

[16]  Y. Sakakibara,et al.  Deep learning integration of molecular and interactome data for protein–compound interaction prediction , 2021, bioRxiv.

[17]  Parvin Razzaghi,et al.  Incorporating part-whole hierarchies into fully convolutional network for scene parsing , 2020, Expert Syst. Appl..

[18]  Jaechang Lim,et al.  PIGNet: a physics-informed deep learning model toward generalized drug–target interaction predictions , 2020, Chemical science.

[19]  X. Xie,et al.  Generative chemistry: drug discovery with deep learning generative models , 2020, Journal of Molecular Modeling.

[20]  Jun Sun,et al.  Diversity-guided Lamarckian random drift particle swarm optimization for flexible ligand docking , 2020, BMC Bioinformatics.

[21]  Parvin Razzaghi,et al.  Learning spatial hierarchies of high-level features in deep neural network , 2020, J. Vis. Commun. Image Represent..

[22]  Parvin Razzaghi,et al.  DeepCDA: deep cross-domain compound-protein affinity prediction through LSTM and convolutional neural networks , 2020, Bioinform..

[23]  Noel Southall,et al.  Novel Consensus Architecture To Improve Performance of Large-Scale Multitask Deep Learning QSAR Models , 2019, J. Chem. Inf. Model..

[24]  Keiji Ogura,et al.  Support Vector Machine model for hERG inhibitory activities based on the integrated hERG database using descriptor selection by NSGA-II , 2019, Scientific Reports.

[25]  Carlo Zaniolo,et al.  Multifaceted protein–protein interaction prediction based on Siamese residual RCNN , 2019, Bioinform..

[26]  Adriano D Andricopulo,et al.  ADMET modeling approaches in drug discovery. , 2019, Drug discovery today.

[27]  Yutaka Saito,et al.  Convolutional neural network based on SMILES representation of compounds for detecting chemical motif , 2018, BMC Bioinformatics.

[28]  Kathia Maria Honorio,et al.  Advances with support vector machines for novel drug discovery , 2018, Expert opinion on drug discovery.

[29]  Sheng-You Huang,et al.  Comprehensive assessment of flexible‐ligand docking algorithms: current effectiveness and challenges , 2018, Briefings Bioinform..

[30]  Jun Sese,et al.  Compound‐protein interaction prediction with end‐to‐end learning of neural networks for graphs and sequences , 2018, Bioinform..

[31]  Alireza Mehridehnavi,et al.  Neural network and deep-learning algorithms used in QSAR studies: merits and drawbacks. , 2018, Drug discovery today.

[32]  Di Wu,et al.  DeepAffinity: Interpretable Deep Learning of Compound-Protein Affinity through Unified Recurrent and Convolutional Neural Networks , 2018, bioRxiv.

[33]  Tao Jiang,et al.  NeoDTI: Neural integration of neighbor information from a heterogeneous network for discovering new drug-target interactions , 2018, bioRxiv.

[34]  Arzucan Özgür,et al.  DeepDTA: deep drug–target binding affinity prediction , 2018, Bioinform..

[35]  Damian Szklarczyk,et al.  The STRING database in 2017: quality-controlled protein–protein association networks, made broadly accessible , 2016, Nucleic Acids Res..

[36]  Jure Leskovec,et al.  node2vec: Scalable Feature Learning for Networks , 2016, KDD.

[37]  Damian Szklarczyk,et al.  STITCH 5: augmenting protein–chemical interaction networks with tissue and affinity data , 2015, Nucleic Acids Res..

[38]  Eric T. Wang,et al.  Design of a bioactive small molecule that targets the myotonic dystrophy type 1 RNA via an RNA motif-ligand database and chemical similarity searching. , 2012, Journal of the American Chemical Society.

[39]  Andrew L. Hopkins,et al.  Drug discovery: Predicting promiscuity , 2009, Nature.

[40]  Christian von Mering,et al.  STITCH: interaction networks of chemicals and proteins , 2007, Nucleic Acids Res..

[41]  John M. Barnard,et al.  Chemical Similarity Searching , 1998, J. Chem. Inf. Comput. Sci..

[42]  David Weininger,et al.  SMILES, a chemical language and information system. 1. Introduction to methodology and encoding rules , 1988, J. Chem. Inf. Comput. Sci..

[43]  OUP accepted manuscript , 2022, Briefings In Bioinformatics.

[44]  Željko Vujović Classification Model Evaluation Metrics , 2021 .

[45]  Peter Willett,et al.  Similarity searching using 2D structural fingerprints. , 2011, Methods in molecular biology.