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BonMOLière: Small-Sized Libraries of Readily Purchasable Compounds, Optimized to Produce Genuine Hits in Biological Screens across the Protein Space

Authors :
Conrad Stork
Neann Mathai
Johannes Kirchmair
Source :
International Journal of Molecular Sciences, International Journal of Molecular Sciences, Vol 22, Iss 7773, p 7773 (2021), Volume 22, Issue 15
Publication Year :
2021
Publisher :
MDPI, 2021.

Abstract

Experimental screening of large sets of compounds against macromolecular targets is a key strategy to identify novel bioactivities. However, large-scale screening requires substantial experimental resources and is time-consuming and challenging. Therefore, small to medium-sized compound libraries with a high chance of producing genuine hits on an arbitrary protein of interest would be of great value to fields related to early drug discovery, in particular biochemical and cell research. Here, we present a computational approach that incorporates drug-likeness, predicted bioactivities, biological space coverage, and target novelty, to generate optimized compound libraries with maximized chances of producing genuine hits for a wide range of proteins. The computational approach evaluates drug-likeness with a set of established rules, predicts bioactivities with a validated, similarity-based approach, and optimizes the composition of small sets of compounds towards maximum target coverage and novelty. We found that, in comparison to the random selection of compounds for a library, our approach generates substantially improved compound sets. Quantified as the “fitness” of compound libraries, the calculated improvements ranged from +60% (for a library of 15,000 compounds) to +184% (for a library of 1000 compounds). The best of the optimized compound libraries prepared in this work are available for download as a dataset bundle (“BonMOLière”). publishedVersion

Details

Language :
English
Database :
OpenAIRE
Journal :
International Journal of Molecular Sciences, International Journal of Molecular Sciences, Vol 22, Iss 7773, p 7773 (2021), Volume 22, Issue 15
Accession number :
edsair.doi.dedup.....34c93ef4e9792cf1851e235395a5aa2f