Independent SE(3)-Equivariant Models for End-to-End Rigid Protein Docking

Ganea, Octavian-Eugen; Huang, Xinyuan; Bunne, Charlotte; Bian, Yatao; Barzilay, Regina; Jaakkola, Tommi S.; Krause, Andreas

doi:10.48550/arxiv.2111.07786

Cited by 26 publications

(41 citation statements)

References 41 publications

(54 reference statements)

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“…Deep learning for protein-protein docking. A related problem is protein-protein docking in which recent methods have performed direct prediction of the complex structure from the two concatenated input sequences using evolutionary information (Evans et al, 2021), or have leveraged geometric deep learning to model rigid body docking (Ganea et al, 2021a) or side-chains structures (Jindal et al, 2021).…”

Section: Related Workmentioning

confidence: 99%

“…Injecting Euclidean 3D transformations into geometric DL models has become possible using equivariant message passing layers (Cohen & Welling, 2016;Thomas et al, 2018;Fuchs et al, 2020;Satorras et al, 2021;Brandstetter et al, 2021;Batzner et al, 2021). Our method follows Ganea et al (2021a) to incorporate SE(3) pairwise equivariance into message passing neural networks for the drug binding problem. However, different from this method, we go beyond rigid docking and model ligand conformational flexibility.…”

Section: Related Workmentioning

confidence: 99%

“…Independent E(3)-equivariant transformations. Similar to (Ganea et al, 2021a), an important geometric inductive bias is to predict the same binding complex no matter how the initial molecules are positioned and oriented in space. This is especially needed for data-scarce problems such as structural drug binding.…”

Section: Equibind Modelmentioning

confidence: 99%

“…This is especially needed for data-scarce problems such as structural drug binding. Towards this goal, we use Independent E(3)-Equivariant Graph Matching Network (IEGMN) (Ganea et al, 2021a) which combines Graph Matching Networks (Li et al, 2019) and E(3)-Equivariant Graph Neural Networks (Satorras et al, 2021). This architecture jointly transforms both features and 3D coordinates to perform intra and inter neural graph message passing.…”

Section: Equibind Modelmentioning

confidence: 99%

“…Here, we introduce EQUIBIND, a novel geometric & graph deep learning model for structural drug binding -Figure 1. Inspired by Ganea et al (2021a), we exploit graph matching networks (GMN) (Li et al, 2019) and E(3)-equivariant graph neural networks (E(3)-GNN) (Satorras et al, 2021) to perform a direct prediction of the ligand-receptor com- plex structure without relying on heavy sampling as prior work, thus achieving significant inference time speed-ups. Moreover, since 3D structural data suffers from scarcity (e.g., only around 19K experimental complexes are publicly available in the PDBbind database), it is crucial to inject the right physical, chemical, or biological inductive biases into DL models to avoid learning these priors from insufficient amounts of data and to create trustable models.…”

Section: Introductionmentioning

confidence: 99%

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EquiBind: Geometric Deep Learning for Drug Binding Structure Prediction

Stark¹,

Ganea²,

Pattanaik³

et al. 2022

Preprint

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Predicting how a drug-like molecule binds to a specific protein target is a core problem in drug discovery. An extremely fast computational binding method would enable key applications such as fast virtual screening or drug engineering. Existing methods are computationally expensive as they rely on heavy candidate sampling coupled with scoring, ranking, and fine-tuning steps. We challenge this paradigm with EQUIBIND, an SE(3)-equivariant geometric deep learning model performing direct-shot prediction of both i) the receptor binding location (blind docking) and ii) the ligand's bound pose and orientation. EquiBind achieves significant speed-ups and better quality compared to traditional and recent baselines. Further, we show extra improvements when coupling it with existing fine-tuning techniques at the cost of increased running time. Finally, we propose a novel and fast fine-tuning model that adjusts torsion angles of a ligand's rotatable bonds based on closed-form global minima of the von Mises angular distance to a given input atomic point cloud, avoiding previous expensive differential evolution strategies for energy minimization.

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Section: Related Workmentioning

confidence: 99%

Section: Related Workmentioning

confidence: 99%

Section: Equibind Modelmentioning

confidence: 99%

Section: Equibind Modelmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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EquiBind: Geometric Deep Learning for Drug Binding Structure Prediction

Stark¹,

Ganea²,

Pattanaik³

et al. 2022

Preprint

Self Cite

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Pre‐Training of Equivariant Graph Matching Networks with Conformation Flexibility for Drug Binding

Jin

Jiang³

et al. 2022

Advanced Science

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The latest biological findings observe that the motionless “lock‐and‐key” theory is not generally applicable and that changes in atomic sites and binding pose can provide important information for understanding drug binding. However, the computational expenditure limits the growth of protein trajectory‐related studies, thus hindering the possibility of supervised learning. A spatial‐temporal pre‐training method based on the modified equivariant graph matching networks, dubbed ProtMD which has two specially designed self‐supervised learning tasks: atom‐level prompt‐based denoising generative task and conformation‐level snapshot ordering task to seize the flexibility information inside molecular dynamics (MD) trajectories with very fine temporal resolutions is presented. The ProtMD can grant the encoder network the capacity to capture the time‐dependent geometric mobility of conformations along MD trajectories. Two downstream tasks are chosen to verify the effectiveness of ProtMD through linear detection and task‐specific fine‐tuning. A huge improvement from current state‐of‐the‐art methods, with a decrease of 4.3% in root mean square error for the binding affinity problem and an average increase of 13.8% in the area under receiver operating characteristic curve and the area under the precision‐recall curve for the ligand efficacy problem is observed. The results demonstrate a strong correlation between the magnitude of conformation's motion in the 3D space and the strength with which the ligand binds with its receptor.

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3DReact: Geometric Deep Learning for Chemical Reactions

van Gerwen,

Briling,

Bunne

et al. 2024

J. Chem. Inf. Model.

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Geometric deep learning models, which incorporate the relevant molecular symmetries within the neural network architecture, have considerably improved the accuracy and data efficiency of predictions of molecular properties. Building on this success, we introduce 3DREACT, a geometric deep learning model to predict reaction properties from three-dimensional structures of reactants and products. We demonstrate that the invariant version of the model is sufficient for existing reaction data sets. We illustrate its competitive performance on the prediction of activation barriers on the GDB7-22-TS, Cyclo-23-TS, and Proparg-21-TS data sets in different atom-mapping regimes. We show that, compared to existing models for reaction property prediction, 3DREACT offers a flexible framework that exploits atommapping information, if available, as well as geometries of reactants and products (in an invariant or equivariant fashion). Accordingly, it performs systematically well across different data sets, atom-mapping regimes, as well as both interpolation and extrapolation tasks.

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Independent SE(3)-Equivariant Models for End-to-End Rigid Protein Docking

Cited by 26 publications

References 41 publications

EquiBind: Geometric Deep Learning for Drug Binding Structure Prediction

EquiBind: Geometric Deep Learning for Drug Binding Structure Prediction

Pre‐Training of Equivariant Graph Matching Networks with Conformation Flexibility for Drug Binding

3DReact: Geometric Deep Learning for Chemical Reactions

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