Article Synopsis
- Post-translational modifications (PTMs) are essential for protein function, and their disruption can lead to diseases, particularly through missense variants.
- PTMAtlas is a new resource that compiles over 397,000 PTM sites from various datasets, while DeepMVP is an advanced deep learning model created to predict these PTM sites more accurately for multiple types of modifications.
- DeepMVP shows significant improvements over existing prediction tools, and its predictions have been validated against real experimental data, making PTMAtlas and DeepMVP valuable resources for protein research and understanding the impacts of genetic variants on PTMs.
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Article Abstract
Post-translational modifications (PTMs) are critical regulators of protein function, and their disruption is a key mechanism by which missense variants contribute to disease. Accurate PTM site prediction using deep learning can help identify PTM-altering variants, but progress has been limited by the lack of large, high-quality training datasets. Here, we introduce PTMAtlas, a curated compendium of 397,524 PTM sites generated through systematic reprocessing of 241 public mass-spectrometry datasets, and DeepMVP, a deep learning framework trained on PTMAtlas to predict PTM sites for phosphorylation, acetylation, methylation, sumoylation, ubiquitination and N-glycosylation. DeepMVP substantially outperforms existing tools across all six PTM types. Its application to predicting PTM-altering missense variants shows strong concordance with experimental results, validated using literature-curated variants and cancer proteogenomic datasets. Together, PTMAtlas and DeepMVP provide a robust platform for PTM research and a scalable framework for assessing the functional consequences of coding variants through the lens of PTMs.
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