Semi-supervised learning for somatic variant calling and peptide identification in personalized cancer immunotherapy

Semi-supervised learning for somatic variant calling and peptide identification in personalized cancer immunotherapy

Personalized cancer vaccines are emerging as one of the most promising approaches to immunotherapy of advanced cancers. However, only a small proportion of the neoepitopes generated by somatic DNA mutations in cancer cells lead to tumor rejection. Since it is impractical to experimentally assess all...

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Bibliographic Details
Published in:BMC bioinformatics Vol. 21; no. Suppl 18; p. 498
Main Authors: Sherafat, Elham, Force, Jordan, Măndoiu, Ion I
Format: Journal Article
Language:English
Published: England BioMed Central 30-12-2020
BMC
Subjects:
Accuracy
Bioinformatics
Cancer
Cancer immunotherapy
Cancer vaccines
Classification
Customization
Datasets
Deoxyribonucleic acid
DNA
Epitopes - immunology
Epitopes - metabolism
Exome sequencing
Genomes
Humans
Immune system
Immunotherapy
Learning
Machine learning
Model accuracy
Mutation
Neoplasms - therapy
Ovarian cancer
Peptide identification
Peptides
Peptides - analysis
Polymorphism, Single Nucleotide
Positive-unlabeled learning
Precision Medicine
Rejection
Semi-supervised learning
Somatic variant calling
Supervised Machine Learning
Tandem Mass Spectrometry
Tumors
Vaccines
Whole Exome Sequencing
Peptide identification
Somatic variant calling
Positive-unlabeled learning
Tandem mass-spectrometry
Exome sequencing
Machine learning
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Summary:Personalized cancer vaccines are emerging as one of the most promising approaches to immunotherapy of advanced cancers. However, only a small proportion of the neoepitopes generated by somatic DNA mutations in cancer cells lead to tumor rejection. Since it is impractical to experimentally assess all candidate neoepitopes prior to vaccination, developing accurate methods for predicting tumor-rejection mediating neoepitopes (TRMNs) is critical for enabling routine clinical use of cancer vaccines. In this paper we introduce Positive-unlabeled Learning using AuTOml (PLATO), a general semi-supervised approach to improving accuracy of model-based classifiers. PLATO generates a set of high confidence positive calls by applying a stringent filter to model-based predictions, then rescores remaining candidates by using positive-unlabeled learning. To achieve robust performance on clinical samples with large patient-to-patient variation, PLATO further integrates AutoML hyper-parameter tuning, classification threshold selection based on spies, and support for bootstrapping. Experimental results on real datasets demonstrate that PLATO has improved performance compared to model-based approaches for two key steps in TRMN prediction, namely somatic variant calling from exome sequencing data and peptide identification from MS/MS data.
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ISSN:1471-2105
1471-2105
DOI:10.1186/s12859-020-03813-x