Deep learning driven de novo drug design based on gastric proton pump structures.
Kazuhiro AbeMami OzakoMiki InukaiYoe MatsuyukiShinnosuke KitayamaChisato KanaiChiaki NagaiChai C GopalasingamChristoph GerleHideki ShigematsuNariyoshi UmekuboSatoshi YokoshimaAtsushi YoshimoriPublished in: Communications biology (2023)
Existing drugs often suffer in their effectiveness due to detrimental side effects, low binding affinity or pharmacokinetic problems. This may be overcome by the development of distinct compounds. Here, we exploit the rich structural basis of drug-bound gastric proton pump to develop compounds with strong inhibitory potency, employing a combinatorial approach utilizing deep generative models for de novo drug design with organic synthesis and cryo-EM structural analysis. Candidate compounds that satisfy pharmacophores defined in the drug-bound proton pump structures, were designed in silico utilizing our deep generative models, a workflow termed Deep Quartet. Several candidates were synthesized and screened according to their inhibition potencies in vitro, and their binding poses were in turn identified by cryo-EM. Structures reaching up to 2.10 Å resolution allowed us to evaluate and re-design compound structures, heralding the most potent compound in this study, DQ-18 (N-methyl-4-((2-(benzyloxy)-5-chlorobenzyl)oxy)benzylamine), which shows a K i value of 47.6 nM. Further high-resolution cryo-EM analysis at 2.08 Å resolution unambiguously determined the DQ-18 binding pose. Our integrated approach offers a framework for structure-based de novo drug development based on the desired pharmacophores within the protein structure.
Keyphrases
- high resolution
- deep learning
- structural basis
- randomized controlled trial
- adverse drug
- binding protein
- drug induced
- single molecule
- mental health
- dna binding
- mass spectrometry
- machine learning
- photodynamic therapy
- electronic health record
- artificial intelligence
- small molecule
- protein protein
- high speed
- transcription factor