Optimization of Cavity-Based Negative Images to Boost Docking Enrichment in Virtual Screening.
Sami T KurkinenJukka V LehtonenOlli Taneli PentikäinenPekka A PostilaPublished in: Journal of chemical information and modeling (2022)
Molecular docking is a key in silico method used routinely in modern drug discovery projects. Although docking provides high-quality ligand binding predictions, it regularly fails to separate the active compounds from the inactive ones. In negative image-based rescoring (R-NiB), the shape/electrostatic potential (ESP) of docking poses is compared to the negative image of the protein's ligand binding cavity. While R-NiB often improves the docking yield considerably, the cavity-based models do not reach their full potential without expert editing. Accordingly, a greedy search-driven methodology, brute force negative image-based optimization (BR-NiB), is presented for optimizing the models via iterative editing and benchmarking. Thorough and unbiased training, testing and stringent validation with a multitude of drug targets, and alternative docking software show that BR-NiB ensures excellent docking efficacy. BR-NiB can be considered as a new type of shape-focused pharmacophore modeling, where the optimized models contain only the most vital cavity information needed for effectively filtering docked actives from the inactive or decoy compounds. Finally, the BR-NiB code for performing the automated optimization is provided free-of-charge under MIT license via GitHub (https://github.com/jvlehtonen/brutenib) for boosting the success rates of docking-based virtual screening campaigns.
Keyphrases
- molecular dynamics simulations
- molecular docking
- molecular dynamics
- protein protein
- deep learning
- small molecule
- crispr cas
- drug discovery
- machine learning
- convolutional neural network
- emergency department
- healthcare
- computed tomography
- optical coherence tomography
- quality improvement
- risk assessment
- binding protein
- human health
- image quality
- data analysis
- single molecule
- social media
- amino acid
- virtual reality