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Pathway-based subnetworks enable cross-disease biomarker discovery

Author

Listed:
  • Syed Haider

    (Ontario Institute for Cancer Research
    University of Cambridge)

  • Cindy Q. Yao

    (Ontario Institute for Cancer Research
    Ontario Institute for Cancer Research
    University of Toronto)

  • Vicky S. Sabine

    (Ontario Institute for Cancer Research)

  • Michal Grzadkowski

    (Ontario Institute for Cancer Research)

  • Vincent Stimper

    (Ontario Institute for Cancer Research)

  • Maud H. W. Starmans

    (Ontario Institute for Cancer Research
    Maastricht University Medical Center)

  • Jianxin Wang

    (Ontario Institute for Cancer Research)

  • Francis Nguyen

    (Ontario Institute for Cancer Research
    University of Toronto)

  • Nathalie C. Moon

    (Ontario Institute for Cancer Research)

  • Xihui Lin

    (Ontario Institute for Cancer Research)

  • Camilla Drake

    (Ontario Institute for Cancer Research)

  • Cheryl A. Crozier

    (Ontario Institute for Cancer Research)

  • Cassandra L. Brookes

    (University of Birmingham)

  • Cornelis J. H. van de Velde

    (Leiden University Medical Center)

  • Annette Hasenburg

    (University Hospital)

  • Dirk G. Kieback

    (Klinikum Vest Medical Center)

  • Christos J. Markopoulos

    (Athens University Medical School)

  • Luc Y. Dirix

    (St. Augustinus Hospital)

  • Caroline Seynaeve

    (Erasmus Medical Center-Daniel den Hoed)

  • Daniel W. Rea

    (University of Birmingham)

  • Arek Kasprzyk

    (Ontario Institute for Cancer Research)

  • Philippe Lambin

    (Maastricht University Medical Center)

  • Pietro Lio’

    (University of Cambridge)

  • John M. S. Bartlett

    (Ontario Institute for Cancer Research)

  • Paul C. Boutros

    (Ontario Institute for Cancer Research
    University of Toronto
    University of Toronto)

Abstract

Biomarkers lie at the heart of precision medicine. Surprisingly, while rapid genomic profiling is becoming ubiquitous, the development of biomarkers usually involves the application of bespoke techniques that cannot be directly applied to other datasets. There is an urgent need for a systematic methodology to create biologically-interpretable molecular models that robustly predict key phenotypes. Here we present SIMMS (Subnetwork Integration for Multi-Modal Signatures): an algorithm that fragments pathways into functional modules and uses these to predict phenotypes. We apply SIMMS to multiple data types across five diseases, and in each it reproducibly identifies known and novel subtypes, and makes superior predictions to the best bespoke approaches. To demonstrate its ability on a new dataset, we profile 33 genes/nodes of the PI3K pathway in 1734 FFPE breast tumors and create a four-subnetwork prediction model. This model out-performs a clinically-validated molecular test in an independent cohort of 1742 patients. SIMMS is generic and enables systematic data integration for robust biomarker discovery.

Suggested Citation

  • Syed Haider & Cindy Q. Yao & Vicky S. Sabine & Michal Grzadkowski & Vincent Stimper & Maud H. W. Starmans & Jianxin Wang & Francis Nguyen & Nathalie C. Moon & Xihui Lin & Camilla Drake & Cheryl A. Cro, 2018. "Pathway-based subnetworks enable cross-disease biomarker discovery," Nature Communications, Nature, vol. 9(1), pages 1-12, December.
    • Handle: RePEc:nat:natcom:v:9:y:2018:i:1:d:10.1038_s41467-018-07021-3
    DOI: 10.1038/s41467-018-07021-3
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    Cited by:

    1. Kuang Du & Shiyou Wei & Zhi Wei & Dennie T. Frederick & Benchun Miao & Tabea Moll & Tian Tian & Eric Sugarman & Dmitry I. Gabrilovich & Ryan J. Sullivan & Lunxu Liu & Keith T. Flaherty & Genevieve M. , 2021. "Pathway signatures derived from on-treatment tumor specimens predict response to anti-PD1 blockade in metastatic melanoma," Nature Communications, Nature, vol. 12(1), pages 1-16, December.

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