Functional annotation of proteins for signaling network inference in non-model species

Molecular biology aims to understand cellular responses and regulatory dynamics in complex biological systems. However, these studies remain challenging in non-model species due to poor functional annotation of regulatory proteins. To overcome this limitation, we develop a multi-layer neural network...

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Bibliographic Details
Published in:Nature communications 2023-08, Vol.14 (1), p.4654-4654, Article 4654
Main Authors: Van den Broeck, Lisa, Bhosale, Dinesh Kiran, Song, Kuncheng, Fonseca de Lima, Cássio Flavio, Ashley, Michael, Zhu, Tingting, Zhu, Shanshuo, Van De Cotte, Brigitte, Neyt, Pia, Ortiz, Anna C., Sikes, Tiffany R., Aper, Jonas, Lootens, Peter, Locke, Anna M., De Smet, Ive, Sozzani, Rosangela
Format: Article
Language:English
Subjects:
631/114/2397
631/449/1659
631/449/2661/2665
82/58
Amino acid sequence
Annotations
Bayesian analysis
Glycine max
Humanities and Social Sciences
Kinases
Molecular biology
multidisciplinary
Multilayers
Neural networks
Oryza sativa
Phosphatase
Phosphorylation
Predictions
Proteins
Regulatory proteins
Science
Science (multidisciplinary)
Sorghum
Sorghum bicolor
Soybeans
Statistical inference
Substrates
Triticum aestivum
Wheat
Zea mays
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Summary:Molecular biology aims to understand cellular responses and regulatory dynamics in complex biological systems. However, these studies remain challenging in non-model species due to poor functional annotation of regulatory proteins. To overcome this limitation, we develop a multi-layer neural network that determines protein functionality directly from the protein sequence. We annotate kinases and phosphatases in Glycine max . We use the functional annotations from our neural network, Bayesian inference principles, and high resolution phosphoproteomics to infer phosphorylation signaling cascades in soybean exposed to cold, and identify Glyma.10G173000 (TOI5) and Glyma.19G007300 (TOT3) as key temperature regulators. Importantly, the signaling cascade inference does not rely upon known kinase motifs or interaction data, enabling de novo identification of kinase-substrate interactions. Conclusively, our neural network shows generalization and scalability, as such we extend our predictions to Oryza sativa , Zea mays , Sorghum bicolor , and Triticum aestivum . Taken together, we develop a signaling inference approach for non-model species leveraging our predicted kinases and phosphatases. An artificial-intelligence network is used to generate highly accurate predictions of proteins’ functionality. The predictions on the identity of regulatory proteins is used to create regulatory networks and make discoveries about complex biological systems.
ISSN:2041-1723
2041-1723
DOI:10.1038/s41467-023-40365-z