PLoS Computational Biology (Oct 2018)

Predicting bioprocess targets of chemical compounds through integration of chemical-genetic and genetic interactions.

  • Scott W Simpkins,
  • Justin Nelson,
  • Raamesh Deshpande,
  • Sheena C Li,
  • Jeff S Piotrowski,
  • Erin H Wilson,
  • Abraham A Gebre,
  • Hamid Safizadeh,
  • Reika Okamoto,
  • Mami Yoshimura,
  • Michael Costanzo,
  • Yoko Yashiroda,
  • Yoshikazu Ohya,
  • Hiroyuki Osada,
  • Minoru Yoshida,
  • Charles Boone,
  • Chad L Myers

DOI
https://doi.org/10.1371/journal.pcbi.1006532
Journal volume & issue
Vol. 14, no. 10
p. e1006532

Abstract

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Chemical-genetic interactions-observed when the treatment of mutant cells with chemical compounds reveals unexpected phenotypes-contain rich functional information linking compounds to their cellular modes of action. To systematically identify these interactions, an array of mutants is challenged with a compound and monitored for fitness defects, generating a chemical-genetic interaction profile that provides a quantitative, unbiased description of the cellular function(s) perturbed by the compound. Genetic interactions, obtained from genome-wide double-mutant screens, provide a key for interpreting the functional information contained in chemical-genetic interaction profiles. Despite the utility of this approach, integrative analyses of genetic and chemical-genetic interaction networks have not been systematically evaluated. We developed a method, called CG-TARGET (Chemical Genetic Translation via A Reference Genetic nETwork), that integrates large-scale chemical-genetic interaction screening data with a genetic interaction network to predict the biological processes perturbed by compounds. In a recent publication, we applied CG-TARGET to a screen of nearly 14,000 chemical compounds in Saccharomyces cerevisiae, integrating this dataset with the global S. cerevisiae genetic interaction network to prioritize over 1500 compounds with high-confidence biological process predictions for further study. We present here a formal description and rigorous benchmarking of the CG-TARGET method, showing that, compared to alternative enrichment-based approaches, it achieves similar or better accuracy while substantially improving the ability to control the false discovery rate of biological process predictions. Additional investigation of the compatibility of chemical-genetic and genetic interaction profiles revealed that one-third of observed chemical-genetic interactions contributed to the highest-confidence biological process predictions and that negative chemical-genetic interactions overwhelmingly formed the basis of these predictions. We also present experimental validations of CG-TARGET-predicted tubulin polymerization and cell cycle progression inhibitors. Our approach successfully demonstrates the use of genetic interaction networks in the high-throughput functional annotation of compounds to biological processes.