SGNet: Folding Symmetrical Protein Complex with Deep Learning (2403.04395v1)
Abstract: Deep learning has made significant progress in protein structure prediction, advancing the development of computational biology. However, despite the high accuracy achieved in predicting single-chain structures, a significant number of large homo-oligomeric assemblies exhibit internal symmetry, posing a major challenge in structure determination. The performances of existing deep learning methods are limited since the symmetrical protein assembly usually has a long sequence, making structural computation infeasible. In addition, multiple identical subunits in symmetrical protein complex cause the issue of supervision ambiguity in label assignment, requiring a consistent structure modeling for the training. To tackle these problems, we propose a protein folding framework called SGNet to model protein-protein interactions in symmetrical assemblies. SGNet conducts feature extraction on a single subunit and generates the whole assembly using our proposed symmetry module, which largely mitigates computational problems caused by sequence length. Thanks to the elaborate design of modeling symmetry consistently, we can model all global symmetry types in quaternary protein structure prediction. Extensive experimental results on a benchmark of symmetrical protein complexes further demonstrate the effectiveness of our method.
- Openfold: Retraining alphafold2 yields new insights into its learning mechanisms and capacity for generalization. bioRxiv, 2022.
- Principles of assembly reveal a periodic table of protein complexes. Science, 2015.
- Accurate prediction of protein structures and interactions using a three-track neural network. Science, 2021.
- Improved prediction of protein-protein interactions using alphafold2. Nature communications, 2022a.
- Predicting the structure of large protein complexes using alphafold and monte carlo tree search. Nature Communications, 2022b.
- Flexible backbone assembly and refinement of symmetrical homomeric complexes. Structure, 2019.
- Improved the protein complex prediction with protein language models. BioRxiv, 2022.
- Protein complex prediction with alphafold-multimer. bioRxiv, 2021.
- Modeling and structure determination of homo-oligomeric proteins: An overview of challenges and current approaches. International journal of molecular sciences, 2021.
- Independent se (3)-equivariant models for end-to-end rigid protein docking. arXiv preprint arXiv:2111.07786, 2021.
- Af2complex predicts direct physical interactions in multimeric proteins with deep learning. Nature communications, 2022.
- Improved docking of protein models by a combination of alphafold2 and cluspro. BioRxiv, 2022.
- Structural symmetry and protein function. Annual Review of Biophysics and Biomolecular Structure, 2000.
- 3dlinker: An e(3) equivariant variational autoencoder for molecular linker design. In ICML, 2022.
- Accurate prediction of protein assembly structure by combining alphafold and symmetrical docking. bioRxiv, 2023.
- Iterative refinement graph neural network for antibody sequence-structure co-design. In ICLR, 2022.
- Automatic procedure for generating symmetry adapted wavefunctions. Journal of Cheminformatics, 2017.
- Highly accurate protein structure prediction with alphafold. Nature, 2021.
- Wolfgang Kabsch. A solution for the best rotation to relate two sets of vectors. Acta Crystallographica Section A: Crystal Physics, Diffraction, Theoretical and General Crystallography, 1976.
- Pesto: parameter-free geometric deep learning for accurate prediction of protein binding interfaces. Nature Communications, 2023.
- Uni-fold symmetry: harnessing symmetry in folding large protein complexes. bioRxiv, 2022.
- Colabfold: making protein folding accessible to all. Nature Methods, 2022.
- Galaxytongdock: Symmetric and asymmetric ab initio protein–protein docking web server with improved energy parameters. Journal of Computational Chemistry, 2019.
- Spherical polar fourier assembly of protein complexes with arbitrary point group symmetry. Journal of Applied Crystallography, 2016.
- Equibind: Geometric deep learning for drug binding structure prediction. In ICML, 2022.
- Harnessing protein folding neural networks for peptide–protein docking. Nature communications, 2022.
- De novo design of protein structure and function with rfdiffusion. Nature, 620(7976):1089–1100, 2023.
- Hsymdock: a docking web server for predicting the structure of protein homo-oligomers with cn or dn symmetry. Nucleic acids research, 2018.
- Complexcontact: a web server for inter-protein contact prediction using deep learning. Nucleic acids research, 2018.
- Scoring function for automated assessment of protein structure template quality. Proteins: Structure, Function, and Bioinformatics, 2004.