English

RapidDock: Unlocking Proteome-scale Molecular Docking

Biomolecules 2024-11-04 v1 Machine Learning

Abstract

Accelerating molecular docking -- the process of predicting how molecules bind to protein targets -- could boost small-molecule drug discovery and revolutionize medicine. Unfortunately, current molecular docking tools are too slow to screen potential drugs against all relevant proteins, which often results in missed drug candidates or unexpected side effects occurring in clinical trials. To address this gap, we introduce RapidDock, an efficient transformer-based model for blind molecular docking. RapidDock achieves at least a 100×100 \times speed advantage over existing methods without compromising accuracy. On the Posebusters and DockGen benchmarks, our method achieves 52.1%52.1\% and 44.0%44.0\% success rates (RMSD<2\text{RMSD}<2\r{A}), respectively. The average inference time is 0.040.04 seconds on a single GPU, highlighting RapidDock's potential for large-scale docking studies. We examine the key features of RapidDock that enable leveraging the transformer architecture for molecular docking, including the use of relative distance embeddings of 33D structures in attention matrices, pre-training on protein folding, and a custom loss function invariant to molecular symmetries.

Keywords

Cite

@article{arxiv.2411.00004,
  title  = {RapidDock: Unlocking Proteome-scale Molecular Docking},
  author = {Rafał Powalski and Bazyli Klockiewicz and Maciej Jaśkowski and Bartosz Topolski and Paweł Dąbrowski-Tumański and Maciej Wiśniewski and Łukasz Kuciński and Piotr Miłoś and Dariusz Plewczynski},
  journal= {arXiv preprint arXiv:2411.00004},
  year   = {2024}
}
R2 v1 2026-06-28T19:43:20.648Z