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Related Concept Videos

Protein Networks02:26

Protein Networks

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An organism can have thousands of different proteins, and these proteins must cooperate to ensure the health of an organism. Proteins bind to other proteins and form complexes to carry out their functions. Many proteins interact with multiple other proteins creating a complex network of protein interactions.
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Many proteins form complexes to carry out their functions, making protein-protein interactions (PPIs) essential for an organism's survival. Most PPIs are stabilized by numerous weak noncovalent chemical forces. The physical shape of the interfaces determines the way two proteins interact. Many globular proteins have closely-matching shapes on their surfaces, which form a large number of weak bonds. Additionally, many PPIs occur between two helices or between a surface cleft and a...
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Many proteins’ biological role depends on their interactions with their ligands, small molecules that bind to specific locations on the protein known as ligand-binding sites. Ligand-binding sites are often conserved among homologous proteins as these sites are critical for protein function.
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Proteins are dynamic macromolecules that carry out a wide variety of essential processes; however, the activities of most proteins depend on their interactions with other molecules or ions, known as ligands.
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Explainable Deep Relational Networks for Predicting Compound-Protein Affinities and Contacts.

Mostafa Karimi1,2, Di Wu1, Zhangyang Wang3,4

  • 1Department of Electrical and Computer Engineering, Texas A&M University, College Station, Texas 77843, United States.

Journal of Chemical Information and Modeling
|December 21, 2020
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Summary
This summary is machine-generated.

Predicting compound-protein affinity without 3D structures is crucial for drug discovery. New machine learning models offer improved interpretability by focusing on intermolecular contacts, enhancing accuracy and understanding.

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Area of Science:

  • Computational chemistry
  • Machine learning
  • Drug discovery

Background:

  • Predicting compound-protein affinity accelerates drug discovery but often requires 3D structure data.
  • Existing structure-free machine learning methods prioritize accuracy over interpretability.
  • Attention mechanisms in current models are insufficient for understanding underlying interactions.

Purpose of the Study:

  • To develop interpretable, structure-free machine learning models for compound-protein affinity prediction.
  • To identify and leverage intermolecular contacts for enhanced interpretability.
  • To assess the interpretability and generalizability of novel deep learning approaches.

Main Methods:

  • Formulated a hierarchical multiobjective learning problem for contact and affinity prediction.
  • Employed hierarchical recurrent neural networks for protein sequences and graph neural networks for compound graphs.
  • Introduced joint attention mechanisms between protein residues and compound atoms.
  • Developed three interpretability-enhancing advances: structure-aware attention regularization, attention supervision using known contacts, and an intrinsically explainable architecture.

Main Results:

  • Achieved generalizable affinity prediction for novel and dissimilar molecules.
  • Significantly improved interpretability compared to state-of-the-art methods.
  • Boosted contact prediction AUPRC by 33- to 35-fold for various test sets.
  • Demonstrated utility in contact-assisted docking and structure-free binding site prediction.

Conclusions:

  • Developed novel, interpretable deep learning models (DeepAffinity+ and DeepRelations) for structure-free compound-protein affinity prediction.
  • These models provide superior interpretability and comparable/better accuracy than existing methods.
  • The approach offers potential for advancing drug discovery through explainable AI.