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Predicting Positive p53 Cancer Rescue Regions Using Most Informative Positive (MIP) Active Learning

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  • Samuel A Danziger
  • Roberta Baronio
  • Lydia Ho
  • Linda Hall
  • Kirsty Salmon
  • G Wesley Hatfield
  • Peter Kaiser
  • Richard H Lathrop

Abstract

Many protein engineering problems involve finding mutations that produce proteins with a particular function. Computational active learning is an attractive approach to discover desired biological activities. Traditional active learning techniques have been optimized to iteratively improve classifier accuracy, not to quickly discover biologically significant results. We report here a novel active learning technique, Most Informative Positive (MIP), which is tailored to biological problems because it seeks novel and informative positive results. MIP active learning differs from traditional active learning methods in two ways: (1) it preferentially seeks Positive (functionally active) examples; and (2) it may be effectively extended to select gene regions suitable for high throughput combinatorial mutagenesis. We applied MIP to discover mutations in the tumor suppressor protein p53 that reactivate mutated p53 found in human cancers. This is an important biomedical goal because p53 mutants have been implicated in half of all human cancers, and restoring active p53 in tumors leads to tumor regression. MIP found Positive (cancer rescue) p53 mutants in silico using 33% fewer experiments than traditional non-MIP active learning, with only a minor decrease in classifier accuracy. Applying MIP to in vivo experimentation yielded immediate Positive results. Ten different p53 mutations found in human cancers were paired in silico with all possible single amino acid rescue mutations, from which MIP was used to select a Positive Region predicted to be enriched for p53 cancer rescue mutants. In vivo assays showed that the predicted Positive Region: (1) had significantly more (p

Suggested Citation

  • Samuel A Danziger & Roberta Baronio & Lydia Ho & Linda Hall & Kirsty Salmon & G Wesley Hatfield & Peter Kaiser & Richard H Lathrop, 2009. "Predicting Positive p53 Cancer Rescue Regions Using Most Informative Positive (MIP) Active Learning," PLOS Computational Biology, Public Library of Science, vol. 5(9), pages 1-12, September.
    • Handle: RePEc:plo:pcbi00:1000498
    DOI: 10.1371/journal.pcbi.1000498
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    References listed on IDEAS

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    1. Wen Xue & Lars Zender & Cornelius Miething & Ross A. Dickins & Eva Hernando & Valery Krizhanovsky & Carlos Cordon-Cardo & Scott W. Lowe, 2007. "Senescence and tumour clearance is triggered by p53 restoration in murine liver carcinomas," Nature, Nature, vol. 445(7128), pages 656-660, February.
    2. Andrea Ventura & David G. Kirsch & Margaret E. McLaughlin & David A. Tuveson & Jan Grimm & Laura Lintault & Jamie Newman & Elizabeth E. Reczek & Ralph Weissleder & Tyler Jacks, 2007. "Restoration of p53 function leads to tumour regression in vivo," Nature, Nature, vol. 445(7128), pages 661-665, February.
    3. Norman E. Sharpless & Ronald A. DePinho, 2007. "Gone but not forgotten," Nature, Nature, vol. 445(7128), pages 606-607, February.
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    1. Armaghan W Naik & Joshua D Kangas & Christopher J Langmead & Robert F Murphy, 2013. "Efficient Modeling and Active Learning Discovery of Biological Responses," PLOS ONE, Public Library of Science, vol. 8(12), pages 1-1, December.

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