Publication date: Sep 10, 2025
Drug repositioning presents a streamlined and cost-efficient way to expand the range of therapeutic possibilities. Drugs with human genetic evidence are more likely to advance successfully through clinical trials towards FDA approval. Single gene-based drug repositioning methods have been implemented, but approaches leveraging a broad spectrum of molecular signatures remain underexplored. We propose a framework called “TReD” (Transcriptome-informed Reversal Distance) that embeds the disease signatures and drug response profiles into a high-dimensional normed space to quantify the reversal potential of candidate drugs in a disease-related cell-based screening. We applied TReD to COVID-19, type 2 diabetes (T2D), and Alzheimer’s disease (AD), identifying 36, 16, and 11 candidate drugs, respectively. Among these, literature supports 69% (25/36), 31% (5/16), and 64% (7/11) of the drugs, with clinical trials conducted for seven COVID-19 candidates and three AD candidates. In summary, we propose a comprehensive genetics-anchored framework integrating population-level signatures and cell-based screening that has the potential to accelerate the search for new therapeutic strategies. Source code and datasets considered in this study are available at Github (https://github. com/zdangm/TReD). An archived snapshot is deposited at Zenodo (https://doi. org/10. 5281/zenodo. 16791909). Supplementary data are available at Bioinformatics online.
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| Efficient | Cell |
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| Genetics | Drug |
| Online | Drugs |
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