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Enter the Matrix: Factorization Uncovers Knowledge from Omics

TRENDS IN GENETICS (2018)

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Journal

TRENDS IN GENETICS
Volume 34, Issue 10, Pages 790-805

Publisher

ELSEVIER SCIENCE LONDON
DOI: 10.1016/j.tig.2018.07.003

Keywords

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Categories

Genetics & Heredity

Funding

  1. National Institutes of Health (NIH) National Cancer institute (NCI)
  2. National Libary of Medicine (NLM) [NCI 2P30CA006516-52, 2P50CA101942-11, NCI R01CA177669, NCI U01CA212007, NLM R01LM011000, NCI P30 CA006973]
  3. Johns Hopkins University Catalyst and Discovery Awards
  4. Johns Hopkins University Institute for Data Intensive Engineering and Science (IDIES)
  5. Johns Hopkins School of Medicine Synergy award
  6. The Gordon and Betty Moore Foundation [GBMF 4552]
  7. Alex's Lemonade Stand Foundation's Childhood Cancer Data Lab
  8. National Institute of Environmental Health Sciences (NIEHS) through the trans-NIH Big Data to Knowledge (BD2K) initiative [K01ES025434]
  9. NIH/National Institute of General Medical Sciences (NIGMS) [P20 COBRE GM103457]
  10. NLM [R01 LM012373]
  11. National Institute of Child Health and Human Development (NICHD) [R01 HD084633]
  12. Department of Defense Breast Cancer Research Program (BCRP) [BC140682P1]
  13. National Science and Engineering Council of Canada (NSERC) [RGPIN-2016-05017]
  14. Windsor-Essex County Cancer Centre Foundation [814221]
  15. Hopkins in Health and Booz Allen Hamilton [90056858]
  16. Russian Foundation for Basic Research [KOMFI 17-00-00208]
  17. NIH [NCI P30 CA006973]
  18. National Research Council of Canada
  19. Chan Zuckerberg Initiative DonorAdvised Fund (DAF) [2018-183444, 2018-128827, 2018-182718]
  20. Silicon Valley Community Foundation
  21. CDMRP [BC140682P1, 793729] Funding Source: Federal RePORTER

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Omics data contain signals from the molecular, physical, and kinetic inter- and intracellular interactions that control biological systems. Matrix factorization (MF) techniquescan reveal low-dimensional structure from high-dimensional data that reflect these interactions. These techniques can uncover new biological knowledge from diverse high-throughput omics data in applications ranging from pathway discovery to timecourse analysis. We review exemplary applications of MF for systems-level analyses. We discuss appropriate applications of these methods, their limitations, and focus on the analysis of results to facilitate optimal biological interpretation. The inference of biologically relevant features with MF enables discovery from high-throughput data beyond the limits of current biological knowledge - answering questions from high-dimensional data that we have not yet thought to ask.

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