AI Article Synopsis
- In bottom-up proteomics, peptide-spectrum matching is essential for accurately identifying peptides and proteins, but existing deep learning models can struggle with generalization due to differences between training and experimental data.
- To improve predictions, a novel test-time training method called PepT3 was developed, which tailors pretrained models to specific experimental conditions, resulting in a 10-40% increase in peptide identification accuracy.
- When applied to patient samples, PepT3 notably improved the identification of tumor-specific immunopeptides by 60%, with many predicted to interact with the patient's specific human leukocyte antigen isoforms; all related datasets are available on Zenodo.org under identifier 8231084.
Article Abstract
In bottom-up proteomics, peptide-spectrum matching is critical for peptide and protein identification. Recently, deep learning models have been used to predict tandem mass spectra of peptides, enabling the calculation of similarity scores between the predicted and experimental spectra for peptide-spectrum matching. These models follow the supervised learning paradigm, which trains a general model using paired peptides and spectra from standard data sets and directly employs the model on experimental data. However, this approach can lead to inaccurate predictions due to differences between the training data and the experimental data, such as sample types, enzyme specificity, and instrument calibration. To tackle this problem, we developed a test-time training paradigm that adapts the pretrained model to generate experimental data-specific models, namely, PepT3. PepT3 yields a 10-40% increase in peptide identification depending on the variability in training and experimental data. Intriguingly, when applied to a patient-derived immunopeptidomic sample, PepT3 increases the identification of tumor-specific immunopeptide candidates by 60%. Two-thirds of the newly identified candidates are predicted to bind to the patient's human leukocyte antigen isoforms. To facilitate access of the model and all the results, we have archived all the intermediate files in Zenodo.org with identifier 8231084.
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| http://dx.doi.org/10.1021/acs.jproteome.3c00229 | DOI Listing |
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