English

Machine learning on DNA-encoded libraries: A new paradigm for hit-finding

Quantitative Methods 2020-06-15 v1 Machine Learning

Abstract

DNA-encoded small molecule libraries (DELs) have enabled discovery of novel inhibitors for many distinct protein targets of therapeutic value through screening of libraries with up to billions of unique small molecules. We demonstrate a new approach applying machine learning to DEL selection data by identifying active molecules from a large commercial collection and a virtual library of easily synthesizable compounds. We train models using only DEL selection data and apply automated or automatable filters with chemist review restricted to the removal of molecules with potential for instability or reactivity. We validate this approach with a large prospective study (nearly 2000 compounds tested) across three diverse protein targets: sEH (a hydrolase), ER{\alpha} (a nuclear receptor), and c-KIT (a kinase). The approach is effective, with an overall hit rate of {\sim}30% at 30 {\textmu}M and discovery of potent compounds (IC50 <10 nM) for every target. The model makes useful predictions even for molecules dissimilar to the original DEL and the compounds identified are diverse, predominantly drug-like, and different from known ligands. Collectively, the quality and quantity of DEL selection data; the power of modern machine learning methods; and access to large, inexpensive, commercially-available libraries creates a powerful new approach for hit finding.

Keywords

Cite

@article{arxiv.2002.02530,
  title  = {Machine learning on DNA-encoded libraries: A new paradigm for hit-finding},
  author = {Kevin McCloskey and Eric A. Sigel and Steven Kearnes and Ling Xue and Xia Tian and Dennis Moccia and Diana Gikunju and Sana Bazzaz and Betty Chan and Matthew A. Clark and John W. Cuozzo and Marie-Aude Guié and John P. Guilinger and Christelle Huguet and Christopher D. Hupp and Anthony D. Keefe and Christopher J. Mulhern and Ying Zhang and Patrick Riley},
  journal= {arXiv preprint arXiv:2002.02530},
  year   = {2020}
}
R2 v1 2026-06-23T13:33:39.696Z