Classification of estrogenic compounds by coupling high content analysis and machine learning algorithms.

Rajib Mukherjee,Adam T Szafran,Fabio Stossi,Michael A Mancini,Lan Zhou,Melis Onel,Efstratios N Pistikopoulos,Dillon Lloyd,Burcu Beykal,Maureen G Mancini,Fred A Wright,Benjamin Althouse

doi:10.1371/journal.pcbi.1008191

Abstract

Environmental toxicants affect human health in various ways. Of the thousands of chemicals present in the environment, those with adverse effects on the endocrine system are referred to as endocrine-disrupting chemicals (EDCs). Here, we focused on a subclass of EDCs that impacts the estrogen receptor (ER), a pivotal transcriptional regulator in health and disease. Estrogenic activity of compounds can be measured by many in vitro or cell-based high throughput assays that record various endpoints from large pools of cells, and increasingly at the single-cell level. To simultaneously capture multiple mechanistic ER endpoints in individual cells that are affected by EDCs, we previously developed a sensitive high throughput/high content imaging assay that is based upon a stable cell line harboring a visible multicopy ER responsive transcription unit and expressing a green fluorescent protein (GFP) fusion of ER. High content analysis generates voluminous multiplex data comprised of minable features that describe numerous mechanistic endpoints. In this study, we present a machine learning pipeline for rapid, accurate, and sensitive assessment of the endocrine-disrupting potential of benchmark chemicals based on data generated from high content analysis. The multidimensional imaging data was used to train a classification model to ultimately predict the impact of unknown compounds on the ER, either as agonists or antagonists. To this end, both linear logistic regression and nonlinear Random Forest classifiers were benchmarked and evaluated for predicting the estrogenic activity of unknown compounds. Furthermore, through feature selection, data visualization, and model discrimination, the most informative features were identified for the classification of ER agonists/antagonists. The results of this data-driven study showed that highly accurate and generalized classification models with a minimum number of features can be constructed without loss of generality, where these machine learning models serve as a means for rapid mechanistic/phenotypic evaluation of the estrogenic potential of many chemicals.

Highlights

Characterization and prediction of the endocrine disruptive potential of complex chemical mixtures are essential to prevent their adverse effects on human health while understanding the biological pathways that lead to such undesirable health outcomes [1]
During and after environmental emergencies, humans are exposed to a number of chemicals, which in return creates an urgent need for the precise identification of their estrogenic potentials using rapid assessment techniques
We have developed an integrated data-driven framework that enables the rapid identification of unknown pure chemicals that affect the estrogen receptor (ER) pathway as either agonists or antagonists

Summary

Introduction

Characterization and prediction of the endocrine disruptive potential of complex chemical mixtures are essential to prevent their adverse effects on human health while understanding the biological pathways that lead to such undesirable health outcomes [1]. The estrogenic potential of different chemicals can be measured using cell-based or cellfree in vitro assays by recording several facets of the ER mechanism of action (i.e., ligand binding, cell proliferation, gene expression, etc.) [5,6,7]. We observed differences in nuclear spot size and intensity when cells were treated with ER agonists and antagonists, which could potentially facilitate the characterization of ligands based upon their effect on ER activity when compared to known agonists and antagonists

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