PAN: Personalized Annotation-Based Networks for the Prediction of Breast Cancer Relapse

The classification of clinical samples based on gene expression data is an important part of precision medicine. In this manuscript, we show how transforming gene expression data into a set of personalized (sample-specific) networks can allow us to harness existing graph-based methods to improve cla...

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Bibliographic Details
Published in:IEEE/ACM transactions on computational biology and bioinformatics 2021-11, Vol.18 (6), p.2841-2847
Main Authors: Nguyen, Thin, Lee, Samuel C., Quinn, Thomas P., Truong, Buu, Li, Xiaomei, Tran, Truyen, Venkatesh, Svetha, Le, Thuc Duy
Format: Article
Language:English
Subjects:
Algorithms
annotation-based networks
Annotations
Breast cancer
Breast Neoplasms - diagnosis
Breast Neoplasms - genetics
Breast Neoplasms - metabolism
Breast Neoplasms - pathology
Classification
Classifiers
Customization
Databases, Genetic
Female
Gene expression
Genomics
Genomics - methods
Humans
Molecular Sequence Annotation - methods
Neoplasm Recurrence, Local - diagnosis
Neoplasm Recurrence, Local - genetics
Neoplasm Recurrence, Local - metabolism
Neoplasm Recurrence, Local - pathology
Networks
Ontologies
Personalized medicine
Precision medicine
Precision Medicine - methods
Protein interaction
Protein Interaction Maps - genetics
Proteins
Sociology
Software
Source code
Transcriptome - genetics
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Summary:The classification of clinical samples based on gene expression data is an important part of precision medicine. In this manuscript, we show how transforming gene expression data into a set of personalized (sample-specific) networks can allow us to harness existing graph-based methods to improve classifier performance. Existing approaches to personalized gene networks have the limitation that they depend on other samples in the data and must get re-computed whenever a new sample is introduced. Here, we propose a novel method, called Personalized Annotation-based Networks (PAN), that avoids this limitation by using curated annotation databases to transform gene expression data into a graph. Unlike competing methods, PANs are calculated for each sample independent of the population, making it a more efficient way to obtain single-sample networks. Using three breast cancer datasets as a case study, we show that PAN classifiers not only predict cancer relapse better than gene features alone, but also outperform PPI (protein-protein interactions) and population-level graph-based classifiers. This work demonstrates the practical advantages of graph-based classification for high-dimensional genomic data, while offering a new approach to making sample-specific networks. Supplementary information: PAN and the baselines are implemented in Python. Source code and data are available at https://github.com/thinng/PAN .
ISSN:1545-5963
1557-9964
DOI:10.1109/TCBB.2021.3076422