Functionally annotating cysteine disulfides and metal binding sites in the plant kingdom using AlphaFold2 predicted structures
- Author
- Patrick Willems (UGent) , Jingjing Huang (UGent) , Joris Messens and Frank Van Breusegem (UGent)
- Organization
- Project
- Abstract
- Deep learning algorithms such as AlphaFold2 predict three-dimensional protein structure with high confidence. The recent release of more than 200 million structural models provides an unprecedented resource for functional protein annotation. Here, we used AlphaFold2 predicted structures of fifteen plant proteomes to functionally and evolutionary analyze cysteine residues in the plant kingdom. In addition to identification of metal ligands coordinated by cysteine residues, we systematically analyzed cysteine disulfides present in these structural predictions. Our analysis demonstrates most of these predicted disulfides are trustworthy due their high agreement (∼96%) with those present in X-ray and NMR protein structures, their characteristic disulfide stereochemistry, the biased subcellular distribution of their proteins and a higher degree of oxidation of their respective cysteines as measured by proteomics. Adopting an evolutionary perspective, zinc binding sites are increasingly present at the expense of iron-sulfur clusters in plants. Interestingly, disulfide formation is increased in secreted proteins of land plants, likely promoting sequence evolution to adapt to changing environments encountered by plants. In summary, Alphafold2 predicted structural models are a rich source of information for studying the role of cysteines residues in proteins of interest and for protein redox biology in general.
- Keywords
- AlphaFold2, Cysteine, Disulfides, Metal ligand, Plants, Redox proteomics, END RULE PATHWAY, REDOX REGULATION, STREPTOPHYTE ALGAE, BONDS, PROTEINS, COMPLEXITY, EFFICIENT, RESOURCE, DOMAINS, ORIGIN
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Citation
Please use this url to cite or link to this publication: http://hdl.handle.net/1854/LU-01GP8VA0S1SY4A95H0302FN9HM
- MLA
- Willems, Patrick, et al. “Functionally Annotating Cysteine Disulfides and Metal Binding Sites in the Plant Kingdom Using AlphaFold2 Predicted Structures.” FREE RADICAL BIOLOGY AND MEDICINE, vol. 194, 2023, pp. 220–29, doi:10.1016/j.freeradbiomed.2022.12.001.
- APA
- Willems, P., Huang, J., Messens, J., & Van Breusegem, F. (2023). Functionally annotating cysteine disulfides and metal binding sites in the plant kingdom using AlphaFold2 predicted structures. FREE RADICAL BIOLOGY AND MEDICINE, 194, 220–229. https://doi.org/10.1016/j.freeradbiomed.2022.12.001
- Chicago author-date
- Willems, Patrick, Jingjing Huang, Joris Messens, and Frank Van Breusegem. 2023. “Functionally Annotating Cysteine Disulfides and Metal Binding Sites in the Plant Kingdom Using AlphaFold2 Predicted Structures.” FREE RADICAL BIOLOGY AND MEDICINE 194: 220–29. https://doi.org/10.1016/j.freeradbiomed.2022.12.001.
- Chicago author-date (all authors)
- Willems, Patrick, Jingjing Huang, Joris Messens, and Frank Van Breusegem. 2023. “Functionally Annotating Cysteine Disulfides and Metal Binding Sites in the Plant Kingdom Using AlphaFold2 Predicted Structures.” FREE RADICAL BIOLOGY AND MEDICINE 194: 220–229. doi:10.1016/j.freeradbiomed.2022.12.001.
- Vancouver
- 1.Willems P, Huang J, Messens J, Van Breusegem F. Functionally annotating cysteine disulfides and metal binding sites in the plant kingdom using AlphaFold2 predicted structures. FREE RADICAL BIOLOGY AND MEDICINE. 2023;194:220–9.
- IEEE
- [1]P. Willems, J. Huang, J. Messens, and F. Van Breusegem, “Functionally annotating cysteine disulfides and metal binding sites in the plant kingdom using AlphaFold2 predicted structures,” FREE RADICAL BIOLOGY AND MEDICINE, vol. 194, pp. 220–229, 2023.
@article{01GP8VA0S1SY4A95H0302FN9HM,
abstract = {{Deep learning algorithms such as AlphaFold2 predict three-dimensional protein structure with high confidence. The recent release of more than 200 million structural models provides an unprecedented resource for functional protein annotation. Here, we used AlphaFold2 predicted structures of fifteen plant proteomes to functionally and evolutionary analyze cysteine residues in the plant kingdom. In addition to identification of metal ligands coordinated by cysteine residues, we systematically analyzed cysteine disulfides present in these structural predictions. Our analysis demonstrates most of these predicted disulfides are trustworthy due their high agreement (∼96%) with those present in X-ray and NMR protein structures, their characteristic disulfide stereochemistry, the biased subcellular distribution of their proteins and a higher degree of oxidation of their respective cysteines as measured by proteomics. Adopting an evolutionary perspective, zinc binding sites are increasingly present at the expense of iron-sulfur clusters in plants. Interestingly, disulfide formation is increased in secreted proteins of land plants, likely promoting sequence evolution to adapt to changing environments encountered by plants. In summary, Alphafold2 predicted structural models are a rich source of information for studying the role of cysteines residues in proteins of interest and for protein redox biology in general.}},
author = {{Willems, Patrick and Huang, Jingjing and Messens, Joris and Van Breusegem, Frank}},
issn = {{0891-5849}},
journal = {{FREE RADICAL BIOLOGY AND MEDICINE}},
keywords = {{AlphaFold2,Cysteine,Disulfides,Metal ligand,Plants,Redox proteomics,END RULE PATHWAY,REDOX REGULATION,STREPTOPHYTE ALGAE,BONDS,PROTEINS,COMPLEXITY,EFFICIENT,RESOURCE,DOMAINS,ORIGIN}},
language = {{eng}},
pages = {{220--229}},
title = {{Functionally annotating cysteine disulfides and metal binding sites in the plant kingdom using AlphaFold2 predicted structures}},
url = {{http://doi.org/10.1016/j.freeradbiomed.2022.12.001}},
volume = {{194}},
year = {{2023}},
}
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