An Integrated Data Driven Approach to Drug Repositioning Using Gene-Disease Associations.

Joseph Mullen,Simon J Cockell,Anil Wipat,Peter Woollard,Ferdinando Di Cunto

doi:10.1371/journal.pone.0155811

Joseph Mullen, Simon J Cockell + Show 3 more

Open Access

https://doi.org/10.1371/journal.pone.0155811

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Journal: PloS one	Publication Date: May 19, 2016
Citations: 41	License type: CC BY 4.0

Affiliation: Newcastle University, GlaxoSmithKline (United Kingdom)

Abstract

Drug development is both increasing in cost whilst decreasing in productivity. There is a general acceptance that the current paradigm of R&D needs to change. One alternative approach is drug repositioning. With target-based approaches utilised heavily in the field of drug discovery, it becomes increasingly necessary to have a systematic method to rank gene-disease associations. Although methods already exist to collect, integrate and score these associations, they are often not a reliable reflection of expert knowledge. Furthermore, the amount of data available in all areas covered by bioinformatics is increasing dramatically year on year. It thus makes sense to move away from more generalised hypothesis driven approaches to research to one that allows data to generate their own hypothesis. We introduce an integrated, data driven approach to drug repositioning. We first apply a Bayesian statistics approach to rank 309,885 gene-disease associations using existing knowledge. Ranked associations are then integrated with other biological data to produce a semantically-rich drug discovery network. Using this network, we show how our approach identifies diseases of the central nervous system (CNS) to be an area of interest. CNS disorders are identified due to the low numbers of such disorders that currently have marketed treatments, in comparison to other therapeutic areas. We then systematically mine our network for semantic subgraphs that allow us to infer drug-disease relations that are not captured in the network. We identify and rank 275,934 drug-disease has_indication associations after filtering those that are more likely to be side effects, whilst commenting on the top ranked associations in more detail. The dataset has been created in Neo4j and is available for download at https://bitbucket.org/ncl-intbio/genediseaserepositioning along with a Java implementation of the searching algorithm.

Highlights

Understanding the molecular mechanisms of diseases is vital within the field of target-based drug discovery
In order to do this we looked at two relevant data types from our network, G-D associations and dd associations
We explored the concept of using a data driven approach to infer novel drug repositioning leads; our results identify diseases of the nervous system as being in need of more small molecule treatments

Summary

Introduction

Understanding the molecular mechanisms of diseases is vital within the field of target-based drug discovery. Due to the complexity of multigenic diseases, allele associations are more probabilistic and less deterministic; the presence of a high-risk allele may only mildly increase the chance of disease [3][4]. For these reasons identifying causal links between a gene and disease experimentally is expensive and time consuming. More recent projects include the Comparative Toxigenomics Database (CTD) [38] and UniProtKB [39] Another source, Orphanet [40], focusses primarily on rare diseases and orphan drugs. The accuracy of automatically extracted associations is not as high as manually curated data, the systematic approach to their construction means that they are more inclusive of true positives

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