Gene expression‐based drug repurposing to target aging

Dönertaş, Handan Melike; Fuentealba, Matías; Partridge, Linda; Thornton, Janet M.

doi:10.1111/acel.12819

Cited by 62 publications

(43 citation statements)

References 46 publications

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“…Three of the top 10 compounds from the combined ranked list have been previously proposed as anti-ageing candidates for humans using bioinformatic analysis. Specifically, tanespimycin, geldanamycin and trichostatin were among the 24 drugs predicted by Dönertas et al (2018)[18] and Calvert et al (2016)[10]. In contrast, we did not observe any overlap with the top results from Fernandes et al (2016)[15] possibly due to the use of a different drug-protein interaction database (DGIdb [46]) or source of ageing data.…”

Section: Discussioncontrasting

confidence: 58%

“…Using annotated databases, our method evaluated the enrichment for pro-longevity of all compounds analysed, rather than only those with significant scores, and we observe that in all cases pro-longevity compounds are ranked higher than expected by chance. Although tanespimycin acts as a senolytic [31], and has been predicted to be geroprotective by two previous studies [10,18], we have demonstrated its effect on longevity experimentally.…”

Section: Discussionmentioning

confidence: 65%

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Using the drug-protein interactome to identify anti-ageing compounds for humans

Fuentealba

Dönertaş

Williams

et al. 2018

Preprint

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Section: Discussioncontrasting

confidence: 58%

Section: Discussionmentioning

confidence: 65%

Using the drug-protein interactome to identify anti-ageing compounds for humans

Fuentealba

Dönertaş

Williams

et al. 2018

Preprint

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“…Examining the top-ranked GO terms that these two methods agreed on (Tables Table 4 and Table 5) gives an overview of the ageing transcriptome, but also reveals some interesting differences and similarities between the studied tissues. The picture given by the global analysis, comprising all 127 datasets, is typical of previous large-scale expression studies and meta-analyses (de Magalhães, Curado and Church, 2009;Yang et al, 2015;Donertas et al, 2018), showing an overexpression of immune genes, stress responses and proteolysis (Table 4A), as well as an underexpression of metabolic and energy metabolism. The preponderance of inflammatory and stress response genes in particular is characteristic of the inflammageing hypothesis (Franceschi et al, 2000), which argues that ageing is caused by steadily failing responses to stress, in particular responses to the increased antigenic load that comes with age.…”

Section: Discussionmentioning

confidence: 83%

Ageing Transcriptome Meta-Analysis Reveals Similarities Between Key Mammalian Tissues

Palmer

Fabris

Doherty

et al. 2019

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Understanding the expression changes that come with age is an important step in understanding the ageing process as a whole. By combining such transcriptomic data with other sources of information, for instance protein-protein interaction (PPI) data, it is possible to make inferences about the functional changes that occur with age. To address this, we conducted a meta-analysis on 127 publicly available microarray and RNA-Seq datasets from mice, rats and humans, to identify genes that are commonly differentially expressed with age in mammals. We also conducted analyses on subsets of these datasets, to produce transcriptomic signatures for brain, heart and muscle tissues, all of which are important tissues in the pathophysiology of ageing. This approach identified the transcriptomic signatures of the ageing system, as well as brain, heart and muscle tissues. We then applied enrichment analysis and machine learning to functionally describe those signatures. This revealed a typical ageing signature including the overexpression of immune and stress response genes and the underexpression of metabolic and developmental genes. Further analysis of the ageing expression signatures revealed that genes differentially expressed with age tend to be broadly expressed across tissues, rather than be tissue-specific, and that the ageing expression signatures (particularly the overexpressed signatures) of the whole system, brain and muscle tend to include genes that are central in PPI networks. We also show that genes underexpressed in the brain are highly central in a co-expression map, suggesting that underexpression of these genes may play a part in cognitive ageing. In sum, we show numerous functional similarities between the ageing

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“…Drug repositioning opens new possibilities for the fast delivery of new treatment options by reducing the time and resources spent on drug development and testing [1,2]. Systematic analysis of concerted transcriptome changes in response to disease and drug action provides a useful concept in this field [63][64][65]. However, it is essential to consider gene expression changes on the whole transcriptome level and not only identify drug-target processes or genes to improve the predictive power of the method but also to understand how off-target genes may interfere with disease development, drug action or be related to the risk of adverse effects.…”

Section: Discussionmentioning

confidence: 99%

Transcriptome-Guided Drug Repositioning

et al. 2019

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Drug repositioning can save considerable time and resources and significantly speed up the drug development process. The increasing availability of drug action and disease-associated transcriptome data makes it an attractive source for repositioning studies. Here, we have developed a transcriptome-guided approach for drug/biologics repositioning based on multi-layer self-organizing maps (ml-SOM). It allows for analyzing multiple transcriptome datasets by segmenting them into layers of drug action- and disease-associated transcriptome data. A comparison of expression changes in clusters of functionally related genes across the layers identifies “drug target” spots in disease layers and evaluates the repositioning possibility of a drug. The repositioning potential for two approved biologics drugs (infliximab and brodalumab) confirmed the drugs’ action for approved diseases (ulcerative colitis and Crohn’s disease for infliximab and psoriasis for brodalumab). We showed the potential efficacy of infliximab for the treatment of sarcoidosis, but not chronic obstructive pulmonary disease (COPD). Brodalumab failed to affect dysregulated functional gene clusters in Crohn’s disease (CD) and systemic juvenile idiopathic arthritis (SJIA), clearly indicating that it may not be effective in the treatment of these diseases. In conclusion, ml-SOM offers a novel approach for transcriptome-guided drug repositioning that could be particularly useful for biologics drugs.

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Gene expression‐based drug repurposing to target aging

Cited by 62 publications

References 46 publications

Using the drug-protein interactome to identify anti-ageing compounds for humans

Using the drug-protein interactome to identify anti-ageing compounds for humans

Ageing Transcriptome Meta-Analysis Reveals Similarities Between Key Mammalian Tissues

Transcriptome-Guided Drug Repositioning

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