Genotoxic mode of action predictions from a multiplexed flow cytometric assay and a machine learning approach

Environ Mol Mutagen. 2016 Apr;57(3):171-89. doi: 10.1002/em.21996. Epub 2016 Jan 13.

Abstract

Several endpoints associated with cellular responses to DNA damage as well as overt cytotoxicity were multiplexed into a miniaturized, "add and read" type flow cytometric assay. Reagents included a detergent to liberate nuclei, RNase and propidium iodide to serve as a pan-DNA dye, fluorescent antibodies against γH2AX, phospho-histone H3, and p53, and fluorescent microspheres for absolute nuclei counts. The assay was applied to TK6 cells and 67 diverse reference chemicals that served as a training set. Exposure was for 24 hrs in 96-well plates, and unless precipitation or foreknowledge about cytotoxicity suggested otherwise, the highest concentration was 1 mM. At 4- and 24-hrs aliquots were removed and added to microtiter plates containing the reagent mix. Following a brief incubation period robotic sampling facilitated walk-away data acquisition. Univariate analyses identified biomarkers and time points that were valuable for classifying agents into one of three groups: clastogenic, aneugenic, or non-genotoxic. These mode of action predictions were optimized with a forward-stepping process that considered Wald test p-values, receiver operator characteristic curves, and pseudo R(2) values, among others. A particularly high performing multinomial logistic regression model was comprised of four factors: 4 hr γH2AX and phospho-histone H3 values, and 24 hr p53 and polyploidy values. For the training set chemicals, the four-factor model resulted in 94% concordance with our a priori classifications. Cross validation occurred via a leave-one-out approach, and in this case 91% concordance was observed. A test set of 17 chemicals that were not used to construct the model were evaluated, some of which utilized a short-term treatment in the presence of a metabolic activation system, and in 16 cases mode of action was correctly predicted. These initial results are encouraging as they suggest a machine learning strategy can be used to rapidly and reliably predict new chemicals' genotoxic mode of action based on data from an efficient and highly scalable multiplexed assay.

Keywords: H2AX; flow cytometry; mode of action; p53; phospho-histone H3.

Publication types

  • Research Support, N.I.H., Extramural

MeSH terms

  • Algorithms
  • Aneugens / toxicity
  • Automation, Laboratory / methods
  • Biomarkers / analysis
  • Cell Line / drug effects
  • DNA Damage / drug effects
  • Flow Cytometry / methods*
  • Histones / metabolism
  • Humans
  • Machine Learning*
  • Mutagenicity Tests / methods*
  • Mutagens / toxicity
  • Reproducibility of Results
  • Tumor Suppressor Protein p53 / genetics

Substances

  • Aneugens
  • Biomarkers
  • H2AX protein, human
  • Histones
  • Mutagens
  • TP53 protein, human
  • Tumor Suppressor Protein p53