A review of network-based approaches to drug repositioning

Shahreza, Maryam Lotfi; Ghadiri, Nasser; Mousavi, Sayed Rasoul; Varshosaz, Jaleh; Green, James R.

doi:10.1093/bib/bbx017

Cited by 245 publications

(206 citation statements)

References 70 publications

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“…From protein-protein interaction prediction [3] to the identification of candidate disease genes to drug repositioning [4] or very recent applications on microbiology [5], it seems to be clear that inference on graph or network data structures can be effective for the purpose of finding relations between entities that interact in such ways [1]. These in silico predictions allow researchers to reduce the search space to focus on a small set of entities that are more likely to be related to the entities of interest.…”

Section: Resultsmentioning

confidence: 99%

ProphTools: general prioritization tools for heterogeneous biological networks

et al. 2017

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BackgroundNetworks have been proven effective representations for the analysis of biological data. As such, there exist multiple methods to extract knowledge from biological networks. However, these approaches usually limit their scope to a single biological entity type of interest or they lack the flexibility to analyze user-defined data.ResultsWe developed ProphTools, a flexible open-source command-line tool that performs prioritization on a heterogeneous network. ProphTools prioritization combines a Flow Propagation algorithm similar to a Random Walk with Restarts and a weighted propagation method. A flexible model for the representation of a heterogeneous network allows the user to define a prioritization problem involving an arbitrary number of entity types and their interconnections. Furthermore, ProphTools provides functionality to perform cross-validation tests, allowing users to select the best network configuration for a given problem. ProphTools core prioritization methodology has already been proven effective in gene-disease prioritization and drug repositioning. Here we make ProphTools available to the scientific community as flexible, open-source software and perform a new proof-of-concept case study on long noncoding RNAs (lncRNAs) to disease prioritization.ConclusionsProphTools is robust prioritization software that provides the flexibility not present in other state-of-the-art network analysis approaches, enabling researchers to perform prioritization tasks on any user-defined heterogeneous network. Furthermore, the application to lncRNA-disease prioritization shows that ProphTools can reach the performance levels of ad hoc prioritization tools without losing its generality.

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Section: Resultsmentioning

confidence: 99%

ProphTools: general prioritization tools for heterogeneous biological networks

et al. 2017

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“…One of the most effective alternative strategies is drug repositioning (or drug 8 repurposing) [6,7], namely finding new pharmaceutical functions for already used drugs. 9 The extensive medical and pharmaceutical experience reveals a surprising propensity 10 towards multiple indications for many drugs [8], and the examples of successful drug 11 repositioning are steadily accumulating. Out of the 90 newly approved drugs in 2016 (a 12 10% decrease from 2015), 25% are repositionings in terms of formulations, combinations, 13 and indications [4].…”

Section: Introductionmentioning

confidence: 99%

“…Some approaches 31 build drug-drug similarity networks, where the similarity is defined based on 32 transcriptional responses [22,23]. These repositioning approaches analyze the network 33 parameters and the node centrality distributions in either drug-drug or drug-target 34 networks, using statistical analysis [10,11,24,25] and machine learning (i.e., graph 35 convolutional networks) [26][27][28][29] to link certain drugs to new pharmacological properties. 36 However, conventional statistics can be misleading when used to predict extreme 37 centrality values, such as degree and betweenness (which particularly indicate 38 nodes/drugs with a high potential for repositioning) [30].…”

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confidence: 99%

“…March 7, 2020 2/22 volumes of useful multi-omics data (genomics, proteomics, metabolomics, and 20 others) [10,11].…”

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confidence: 99%

“…• The recent developments in physics, computer science, and computer engineering 25 have created efficient methods and technologies for data exploration and mining, 26 such as complex network analysis, machine learning, or deep learning [11,[14][15][16][17][18]. 27…”

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Uncovering new drug properties in target-based drug-drug similarity networks

Udrescu

Bogdan

Chiș

et al. 2020

Preprint

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Despite recent advances in bioinformatics, systems biology, and machine learning, the accurate prediction of drug properties remains an open problem. Indeed, because the biological environment is a complex system, the traditional approach -based on knowledge about the chemical structures -cannot fully explain the nature of interactions between drugs and biological targets. Consequently, in this paper, we propose an unsupervised machine learning approach that uses the information we know about drug-target interactions to infer drug properties. To this end, we define drug similarity based on drug-target interactions and build a weighted Drug-Drug Similarity Network according to the drug-drug similarity relationships. Using an energy-model network layout, we generate drug communities that are associated with specific, dominant drug properties. However, 13.59% of the drugs in these communities seem not to match the dominant pharmacologic property. Thus, we consider them as drug repurposing hints. The resources required to test all these repurposing hints are considerable. Therefore we introduce a mechanism of prioritization based on the betweenness/degree node centrality. By using betweenness/degree as an indicator of drug repurposing potential, we identify the drug Meprobamate as a possible antifungal. Finally, we use a robust test procedure, based on molecular docking, to further confirm the repurposing of Meprobamate. Author summaryWe address the salient problem of drug repurposing by using an unsupervised machine learning technique (i.e., clustering) on a drug network (i.e., nodes represent drugs and links represent relationships between two drugs). To this end, we build a drug-drug similarity network (DDSN) using information about drug-target interactions, then March 7, 2020 1/22 perform network clustering and associate the clusters with drug properties. To validate our DDSN clustering approach, we use an old drug database to render the cluster-property pairs and then verify them with the information from the latest database. Indeed, the properties uncovered with our DDSN clustering are confirmed for 86.41% of the drugs; for the remaining 13.59%, we assume that the associated property is not fortuitous, thus representing repositioning hints. As the number of repositioning hints is considerable, we prioritize them with a new approach, based on the node betweenness/degree ratio. The prioritization of repositioning hints renders the repurposing of Meprobamate (known as a hypnotic and sedative drug) as an antifungal drug. We also test and confirm the robustness of our hypothesis using an original, formal procedure based on computer-simulated molecular docking. 14 development (R&D) time and costs, as well as medication risks, which makes it 15particularly efficient for developing orphan/rare disease therapies [8,9]. 16The recent developments confirm computational methods as powerful tools for drug 17 repositioning: 18• The trivialization/spread of omics analytical approaches have generated significant 19March 7, 2020...

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Suramin, screened from an approved drug library, inhibits HuR functions and attenuates malignant phenotype of oral cancer cells

et al. 2018

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AU‐rich elements (ARE) exist in the 3′‐untranslated regions of the mRNA transcribed from cell growth‐related genes such as proto‐oncogenes, cyclin‐related genes, and growth factors. HuR binds and stabilizes ARE‐mRNA. HuR is expressed abundantly in cancer cells and related malignant phenotypes. HuR knockdown attenuates the malignant phenotype of oral cancer cells. In this study, we screened 1570 compounds in the approved drug library by differential scanning fluorimetry (DSF) to discover a HuR‐targeted compound. Firstly, 55 compounds were selected by DSF. Then, 8 compounds that showed a shift in the melting temperature value in a concentration‐dependent manner were selected by DSF. Of them, suramin, an anti‐trypanosomal drug, binds to HuR, exhibiting fast‐on and fast‐off kinetic behavior on surface plasmon resonance (SPR). We confirmed that suramin significantly decreased mRNA and protein expression of cyclin A2 and cyclin B1. The cyclin A2 and cyclin B1 mRNAs were destabilized by suramin. Furthermore, the motile and invasive activities of a tongue carcinoma cell line treated with suramin were markedly lower than those of control cells. The above findings suggest that suramin binds to HuR and inhibits its function. We also showed that the anticancer effects of suramin were caused by the inhibition of HuR function, indicating its potential as a novel therapeutic agent in the treatment of oral cancer. Our results suggest that suramin, via its different mechanism, may effectively suppress progressive oral cancer that cannot be controlled using other anticancer agents.

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A review of network-based approaches to drug repositioning

Cited by 245 publications

References 70 publications

ProphTools: general prioritization tools for heterogeneous biological networks

ProphTools: general prioritization tools for heterogeneous biological networks

Uncovering new drug properties in target-based drug-drug similarity networks

Suramin, screened from an approved drug library, inhibits HuR functions and attenuates malignant phenotype of oral cancer cells

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