Predicting drug―target interactions from chemical and genomic kernels using Bayesian matrix factorization

Identifying interactions between drug compounds and target proteins has a great practical importance in the drug discovery process for known diseases. Existing databases contain very few experimentally validated drug-target interactions and formulating successful computational methods for predicting...

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Bibliographic Details
Published in:Bioinformatics 2012-09, Vol.28 (18), p.2304-2310
Main Author: GONEN, Mehmet
Format: Article
Language:English
Subjects:
Algorithms
Bayes Theorem
Biological and medical sciences
Drug Discovery
Enzymes - drug effects
Fundamental and applied biological sciences. Psychology
General aspects
Genomics
Humans
Ion Channels - drug effects
Mathematics in biology. Statistical analysis. Models. Metrology. Data processing in biology (general aspects)
Pharmaceutical Preparations - chemistry
Proteins - chemistry
Proteins - drug effects
Proteins - genetics
Receptors, Cytoplasmic and Nuclear - drug effects
Receptors, G-Protein-Coupled - drug effects
Sequence Analysis, Protein
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Summary:Identifying interactions between drug compounds and target proteins has a great practical importance in the drug discovery process for known diseases. Existing databases contain very few experimentally validated drug-target interactions and formulating successful computational methods for predicting interactions remains challenging. In this study, we consider four different drug-target interaction networks from humans involving enzymes, ion channels, G-protein-coupled receptors and nuclear receptors. We then propose a novel Bayesian formulation that combines dimensionality reduction, matrix factorization and binary classification for predicting drug-target interaction networks using only chemical similarity between drug compounds and genomic similarity between target proteins. The novelty of our approach comes from the joint Bayesian formulation of projecting drug compounds and target proteins into a unified subspace using the similarities and estimating the interaction network in that subspace. We propose using a variational approximation in order to obtain an efficient inference scheme and give its detailed derivations. Finally, we demonstrate the performance of our proposed method in three different scenarios: (i) exploratory data analysis using low-dimensional projections, (ii) predicting interactions for the out-of-sample drug compounds and (iii) predicting unknown interactions of the given network. Software and Supplementary Material are available at http://users.ics.aalto.fi/gonen/kbmf2k. mehmet.gonen@aalto.fi Supplementary data are available at Bioinformatics online.
ISSN:1367-4803
1367-4811
1460-2059
DOI:10.1093/bioinformatics/bts360