Generation of 3D Molecules in Pockets via Language Model
- URL: http://arxiv.org/abs/2305.10133v3
- Date: Mon, 11 Dec 2023 08:29:29 GMT
- Title: Generation of 3D Molecules in Pockets via Language Model
- Authors: Wei Feng (1), Lvwei Wang (1), Zaiyun Lin (1), Yanhao Zhu (1), Han Wang
(1), Jianqiang Dong (1), Rong Bai (1), Huting Wang (1), Jielong Zhou (1), Wei
Peng (2), Bo Huang (1), Wenbiao Zhou (1) ((1) Beijing StoneWise Technology Co
Ltd (2) Innovation Center for Pathogen Research Guangzhou Laboratory)
- Abstract summary: Generative models for molecules based on sequential line notation (e.g. SMILES) or graph representation have attracted an increasing interest in the field of structure-based drug design.
We introduce Lingo3DMol, a pocket-based 3D molecule generation method that combines language models and geometric deep learning technology.
- Score: 0.0
- License: http://creativecommons.org/licenses/by/4.0/
- Abstract: Generative models for molecules based on sequential line notation (e.g.
SMILES) or graph representation have attracted an increasing interest in the
field of structure-based drug design, but they struggle to capture important 3D
spatial interactions and often produce undesirable molecular structures. To
address these challenges, we introduce Lingo3DMol, a pocket-based 3D molecule
generation method that combines language models and geometric deep learning
technology. A new molecular representation, fragment-based SMILES with local
and global coordinates, was developed to assist the model in learning molecular
topologies and atomic spatial positions. Additionally, we trained a separate
noncovalent interaction predictor to provide essential binding pattern
information for the generative model. Lingo3DMol can efficiently traverse
drug-like chemical spaces, preventing the formation of unusual structures. The
Directory of Useful Decoys-Enhanced (DUD-E) dataset was used for evaluation.
Lingo3DMol outperformed state-of-the-art methods in terms of drug-likeness,
synthetic accessibility, pocket binding mode, and molecule generation speed.
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