Deep-learning-based de novo discovery and design of therapeutics that reverse disease-associated transcriptional phenotypes
Summary
Identifying drugs that reverse disease-associated transcriptomic features has been widely explored for drug repurposing, but its potential for de novo drug discovery remains underexplored. Here, we present gene expression profile predictor on chemical structures (GPS), a deep-learning-based drug discovery platform, guided by transcriptomic features, that screens large compound libraries and optimizes lead molecules. We first develop a model that captures transcriptomic perturbation signatu
Content
# Deep-learning-based de novo discovery and design of therapeutics that reverse disease-associated transcriptional phenotypes
*Published: 2026 Apr 30*
Identifying drugs that reverse disease-associated transcriptomic features has
been widely explored for drug repurposing, but its potential for de novo drug
discovery remains underexplored. Here, we present gene expression profile
predictor on chemical structures (GPS), a deep-learning-based drug discovery
platform, guided by transcriptomic features, that screens large compound
libraries and optimizes lead molecules. We first develop a model that captures
transcriptomic perturbation signatures solely from chemical structures and
deploy it to library compounds. We refine scoring methods and employ a
tree-search method for optimization. By incorporating structure-gene-activity
relationships, we uncover drug mechanisms from transcriptomic data. We evaluate
GPS across multiple diseases and conduct extensive validation in two cases. In
hepatocellular carcinoma, we discover two unique compound series with favorable
cellular selectivity and in vivo efficacy. In idiopathic pulmonary fibrosis, we
identify one repurposing candidate and one novel anti-fibrotic compound by
reversing gene expression of multiple distinct cell types derived from
single-cell transcriptomics.
DOI: 10.1016/j.cell.2026.02.016