Improving prediction of drug-target interactions based on fusing multiple features with data balancing and feature selection techniques

Improving prediction of drug-target interactions based on fusing multiple features with data balancing and feature selection techniques

Drug discovery relies on predicting drug-target interaction (DTI), which is an important challenging task. The purpose of DTI is to identify the interaction between drug chemical compounds and protein targets. Traditional wet lab experiments are time-consuming and expensive, that's why in recen...

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Veröffentlicht in:PloS one 2023-08, Vol.18 (8), p.e0288173-e0288173
Hauptverfasser: Khojasteh, Hakimeh, Pirgazi, Jamshid, Ghanbari Sorkhi, Ali
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Sprache:eng
Schlagworte:
Algorithms
Amino acids
Analysis
Biology and Life Sciences
Candidates
Chemical compounds
Classifiers
Computer and Information Sciences
Computer applications
Datasets
Deep learning
Drug discovery
Drugs
Enzymes
Evaluation
Feature selection
Kinases
Machine learning
Medicine and Health Sciences
Methods
Neural networks
Performance evaluation
Performance prediction
Physical Sciences
Proteins
R&D
Research & development
Research and Analysis Methods
Source code
Support vector machines
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Pirgazi, Jamshid
Ghanbari Sorkhi, Ali
description Drug discovery relies on predicting drug-target interaction (DTI), which is an important challenging task. The purpose of DTI is to identify the interaction between drug chemical compounds and protein targets. Traditional wet lab experiments are time-consuming and expensive, that's why in recent years, the use of computational methods based on machine learning has attracted the attention of many researchers. Actually, a dry lab environment focusing more on computational methods of interaction prediction can be helpful in limiting search space for wet lab experiments. In this paper, a novel multi-stage approach for DTI is proposed that called SRX-DTI. In the first stage, combination of various descriptors from protein sequences, and a FP2 fingerprint that is encoded from drug are extracted as feature vectors. A major challenge in this application is the imbalanced data due to the lack of known interactions, in this regard, in the second stage, the One-SVM-US technique is proposed to deal with this problem. Next, the FFS-RF algorithm, a forward feature selection algorithm, coupled with a random forest (RF) classifier is developed to maximize the predictive performance. This feature selection algorithm removes irrelevant features to obtain optimal features. Finally, balanced dataset with optimal features is given to the XGBoost classifier to identify DTIs. The experimental results demonstrate that our proposed approach SRX-DTI achieves higher performance than other existing methods in predicting DTIs. The datasets and source code are available at: https://github.com/Khojasteh-hb/SRX-DTI.
doi_str_mv 10.1371/journal.pone.0288173
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The purpose of DTI is to identify the interaction between drug chemical compounds and protein targets. Traditional wet lab experiments are time-consuming and expensive, that's why in recent years, the use of computational methods based on machine learning has attracted the attention of many researchers. Actually, a dry lab environment focusing more on computational methods of interaction prediction can be helpful in limiting search space for wet lab experiments. In this paper, a novel multi-stage approach for DTI is proposed that called SRX-DTI. In the first stage, combination of various descriptors from protein sequences, and a FP2 fingerprint that is encoded from drug are extracted as feature vectors. A major challenge in this application is the imbalanced data due to the lack of known interactions, in this regard, in the second stage, the One-SVM-US technique is proposed to deal with this problem. Next, the FFS-RF algorithm, a forward feature selection algorithm, coupled with a random forest (RF) classifier is developed to maximize the predictive performance. This feature selection algorithm removes irrelevant features to obtain optimal features. Finally, balanced dataset with optimal features is given to the XGBoost classifier to identify DTIs. The experimental results demonstrate that our proposed approach SRX-DTI achieves higher performance than other existing methods in predicting DTIs. 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subjects Algorithms
Amino acids
Analysis
Biology and Life Sciences
Candidates
Chemical compounds
Classifiers
Computer and Information Sciences
Computer applications
Datasets
Deep learning
Drug discovery
Drugs
Enzymes
Evaluation
Feature selection
Kinases
Machine learning
Medicine and Health Sciences
Methods
Neural networks
Performance evaluation
Performance prediction
Physical Sciences
Proteins
R&D
Research & development
Research and Analysis Methods
Source code
Support vector machines
title Improving prediction of drug-target interactions based on fusing multiple features with data balancing and feature selection techniques
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