Predicting Drug–Target Interactions Using Probabilistic Matrix Factorization

Çobanoğlu, Murat Can; Liu, Chang; Hu, Feizhuo; Oltvai, Zoltán N.; Bahar, İvet

doi:10.1021/ci400219z

Cited by 167 publications

(145 citation statements)

References 57 publications

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“…To date, several pro-and retrospective studies report successful applications of AL strategies throughout different fields of research [27][28][29][30][31][32][33][34][35][36][37][38][39][40][41][42][43][44][45][46]. In the area of drug discovery, active learning has been shown to efficiently derive high-performance prediction models based on small subsets of input data [32,34,39,46].…”

Section: Introductionmentioning

confidence: 99%

“…In the area of drug discovery, active learning has been shown to efficiently derive high-performance prediction models based on small subsets of input data [32,34,39,46]. Furthermore, actively trained models not only reached significantly higher hit rates compared to experimental standards which frequently remain below 1 % in cases of unbiased chemical libraries [34,39,40,[47][48][49], but such models also contributed to successful identification of novel bioactive compounds [33,36,42] and cancer rescue mutants of p53 [31]. Overall, AL approaches bear the potential to improve drug discovery processes by increasing hit rates, reducing the amount of time-and cost-intensive experimentation, and accelerate hit-to-lead processes through integration into a feedback-driven experimentation workflow [33,36,42,43,50].…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Small Random Forest Models for Effective Chemogenomic Active Learning

Rakers

Reker

Brown

2017

J. Comput. Aided Chem.

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The identification of new compound-protein interactions has long been the fundamental quest in the field of medicinal chemistry. With increasing amounts of biochemical data, advanced machine learning techniques such as active learning have been proven to be beneficial for building high-performance prediction models upon subsets of such complex data. In a recently published paper, chemogenomic active learning had been applied to the interaction spaces of kinases and G protein-coupled receptors featuring over 150,000 compound-protein interactions. Prediction models were actively trained based on random forest classification using 500 decision trees per experiment. In a new direction for chemogenomic active learning, we address the question of how forest size influences model evolution and performance. In addition to the original chemogenomic active learning findings that highly predictive models could be constructed from a small fraction of the available data, we find here that that model complexity as viewed by forest size can be reduced to one-fourth or one-fifth of the previously investigated forest size while still maintaining reliable prediction performance. Thus, chemogenomic active learning can yield predictive models with reduced complexity based on only a fraction of the data available for model construction.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Small Random Forest Models for Effective Chemogenomic Active Learning

Rakers

Reker

Brown

2017

J. Comput. Aided Chem.

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“…The chemical structure similarity between compounds is calculated by using SIMCOMP, which gives a score based on the size of common substructures with graph alignment (Hattori et al 2003). The chemical structure similarity has been widely applied in drug-target interaction prediction (Cobanoglu et al 2013).…”

Section: Data Preparationmentioning

confidence: 99%

“…The Gaussian interaction profile kernel and weighted nearest neighbour are integrated for drug-target interactions prediction (Van Laarhoven 2013). In addition, the Bayesian matrix factorization and binary classification (Gönen 2012) and probabilistic matrix factorization (Cobanoglu et al 2013) are proposed to detect drug-target interactions.…”

Section: Introductionmentioning

confidence: 99%

Predicting drug-target interaction based on sequence and structure information

Lan

Wang

et al. 2015

IFAC-PapersOnLine

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It is well known that discovering a new drug is a cumbersome, time-consuming and expensive process. Computational approaches for identifying interactions between drug compounds and target proteins have become important in drug discovery which is helpful to reduce these obstacles. The difficulties of drug-target interaction identification include the lack of known drug-target associations and no experimentally verified negative examples. In this study, we present a method, called PUDT, to predict drug-target interactions. Instead of treating unknown interactions as negative examples, we consider unknown interactions as unlabeled examples. The unlabeled examples are divided into two parts: reliable negative examples and likely negative examples based on protein structure similarity.Then, a weighted support vector machine is used to build a classifier to predict drug-target interactions based on protein sequence and drug structure information. Four data sets (enzymes, ion channels, GPCRs and nuclear receptors) are used to evaluate the performance of the proposed method PUDT. The experimental results demonstrate that our method PUDT outperforms recent state-of-the-art approaches.

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“…The Gaussian interaction profile kernel and weighted nearest neighbour were integrated for drug-target interaction prediction [23]. The Bayesian matrix factorization and binary classification [24] and probabilistic matrix factorization [25] were proposed to detect drug-target interactions. The common limitation of these supervised learning approaches is to treat unknown drug-target interactions as negative samples, which may affect predictive accuracy.…”

Section: Introductionmentioning

confidence: 99%